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Category: Energy Crunch

[Friends, I have suffered a little writer’s block, so I resolved to spark some creativity in myself by joining a little local writers group. The leader of the group suggested a title, I Googled the allegedly fictional location and found it existed, and that it was near a wind farm; and Google Maps led me to the rest of my research and inspiration for this piece. Caveat Lector : it’s fictional, even though a lot of it is factual. Also, it’s only a draft, but it needs to settle for a while before I can refine/sift it. ]

Jumping Off Mount Gideon [1]
by Jo Abbess
DRAFT

In the blue-green sun-kissed uplands, west of the sediment-spewing Chocolate River sprung at Petitcodiac village, and north of the shrunken Shepody Lake, its feeder tributaries re-engineered hundreds of years ago; north still of the shale flats jutting out into the Bay of Fundy, rises Mount Gideon, shrouded in managed native Canadian spruce, pine and fir. Part of the ranging, half-a-billion-year-old craton of the Caledonian Highlands of New Brunswick, it is solid ground, and its first European inhabitants must have been hardy. Looking up, the early settlers must have seen the once-bare hinterland looming over the mudstone and sandstone shoreline, with its steep gullied waterways carved by the receding pre-historic icesheets, and it must have been redolent of the mountainous “encampments of the just” [2] where the Biblical Gideon of the Book of Judges [3] trained his elite crack troops and plotted his revenge against the hordes of ravaging Midianites. The fur-trappers and gravel miners on the eve of the 18th Century built a community by the bay, and drove a winding road up through Mount Gideon’s ravines and over its heights, a byway long since eroded and erased and replaced by a functional forestry access track. Ethnic cleansing of the first-come Acadians in the summer of 1755 destroyed much of the larger settlements in the region of Chipoudy, henceforth anglicised to Shepody. Two groups of deportation vigilantes, originally tasked with taking prisoners, burned down the infrastructure and put to death those who hadn’t fled to the woods, and since that day, nobody really lives up on the mount, aside from the occasional lumberjack in his trailer home cached off New Ireland Road, and the odd temporary bivouac of touring hippy couples, en route from Hopewell Rocks to Laverty Falls on the Moosehorn Trail in the national park, via the Caledonia Gorge and Black Hole on the Upper Salmon River. These days there is no risk of social crisis, but an insidious slow-moving environmental crisis is underway. Streams falling from Mount Gideon, spider lines scratched on early parish maps, the West River and Beaver Brook, no longer flow year-round, and there’s very little freshwater locally, apart from a few scattered tarns, cradled in the impervious igneous, plutonic rock of the hinterland. Rainwater does support the timber plantations, for now, but drought and beetle are a rising threat, brought on by creeping climate change. Humans may no longer be setting fires, but Nature is, because human beings have interfered with the order of things.

Mount Gideon isn’t really a proper peak : from its summit it’s clear it’s only a local undulation like other protruding spine bones in the broad back of the hills. Its cap sprouts industrial woodland, planted in regular patterns visible from space, reached by gravel-bordered runnelled dirt track. The former ancient water courses that fall away sharply from the highest point on the weald are filled with perilously-rooted trees, leaning haphazardly out from the precipitous banks of the ravines. The plantations and roadside thickets obscure the view of Chignecto Bay and the strong-tided Minas Passage, where the tidal turbine energy project is still being developed. With no coastal horizon, this could be hundreds of kilometres from anywhere, in the centre of an endless Avalonian Terrane. A silvicultural and latterly agroforestry economy that grew from the wealth of wood eventually developed a dependence on fossil fuels, but what thin coal seams locally have long been exhausted, and the metamorphic mass underfoot salts no petroleum oil or gas beneath. Tanker ship and truck brought energy for tractor and homestead for decades, but seeing little future in the black stuff, local sparsely-populated Crown Land was designated for renewable energy. Just to the north of Mount Gideon lie the Kent Hills, a scene of contention and social protest when the wind farm was originally proposed. For some, wind turbines would mechanise the landscape, cause frequency vibration sickness, spark forest fires from glinting blades, induce mass migraine from flickering sweeps of metal. Windmills were seen as monsters, but sense prevailed, through the normal processes of local democracy and municipal authority, and even a wind farm expansion came about. It is true that engineering giants have cornered the market in the first development sweep of wind power – those hoping for small-scale, locally-owned new energy solutions to the carbon crisis have had to relent and accept that only big players have the economic power to kickstart new technologies at scale. There are some who suspect that the anti-turbine groups were sponsored secretly by the very firms who wanted to capitalise on the ensuing vacuum in local energy supply; and that this revolt went too far. There was speculation about sabotage when one of the wind turbine nacelles caught fire a while back and became a sneering viral internet sensation. When the shale gas 1970s extraction technology revival circus came to Nova Scotia, the wind power companies were thought to have been involved in the large protest campaign that resulted in a New Brunswick moratorium on hydraulic fracturing in the coastal lowlands. The geology was anyways largely against an expansion in meaningful fossil fuel mining in the area, and the central Precarboniferous massif would have held no gas of any kind, so this was an easily-won regulation, especially considering the risks to the Chignecto Bay fisheries from mining pollution.

TransAlta, they of “Clean Power, Today and Tomorrow”, sensed an prime moment for expansion. They had already forged useful alliances with the local logging companies during the development of Kent Hills Wind Farm, and so they knew that planning issues could be overcome. However, they wanted to appease the remnant of anti-technologists, so they devised a creative social engagement plan. They invited energy and climate change activists from all over Nova Scotia, Newfoundland, and the rest of Quebec to organise a pro-wind power camp and festival on the top of Mount Gideon. The idea was to celebrate wind power in a creative and co-operative way. The Crown Land was clearcut of trees as the first stage of the wind farm expansion, so the location was ideal. To enable the festival to function, water was piped to the summit, teepees and yurts were erected, and a local food delivery firm was hired to supply. The ambition of the cultural committee was to create an open, welcoming space with plenty of local colour and entertainment, inviting visitors and the media to review plans for the new wind farm. The festival was an international Twitter success, and attracted many North American, European and even Australasian revellers, although a small anarchist group from the French national territory in St Pierre et Miquelon created a bit of a diplomatic incident by accidentally setting fire to some overhanging trees in a ravine during a hash-smoking party.

Unbeknownst to the festival committee, a small and dedicated group of activists used the cover of the camp to plan a Gideon-style resistance to the Energy East pipeline plan. TransCanada wanted to bring heavy tar sands oil, blended with American light petroleum condensate, east from Alberta. The recent history of onshore oil pipelines and rail consignments was not encouraging – major spills had already taken place – and several disastrous accidents, such as the derailment and fireball at Plaster Rock, where the freight was routed by track to Irving Refinery. The original Energy East plan was to bring oil to the Irving Oil Canaport facility at Saint John, but a proposal had been made to extend the pipeline to the Atlantic coast. The new route would have to either make its circuitous way through Moncton, or cross under the Bay of Fundy, in order to be routed to Canso on the eastern side of Nova Scotia. The Energy East pipeline was already being criticised because of its planned route near important waterways and sensitive ecological sites. And the activist group had discovered that TransCanada had contracted a site evaluation at Cape Enrage on the western shore of the bay. Land jutted out into the water from here, making it the shortest crossing point to Nova Scotia. To route a pipeline here would mean it would have to cross Fundy National Park, sensitive fish and bird wading areas on the marshes and mudflats of the Waterside and Little Ridge, and cross over into the Raven Head Wilderness Area.

Gideon’s campaign had succeeded because of three things. His army had been whittled down to a compact, focused, elite force; they had used the element of surprise, and they had used the power of the enemy against itself. The activist group decided on a high level of secrecy about their alliance, but part of their plan was very public. They were divided into three groups : the Wasps, the Eagles and the Hawks. The Wasps would be the hidden force. They would construct and test drones, jumping off Mount Gideon, and flown out at night down the old river gullies, their route hidden by the topography, to spy on the TransCanada surface works. The plan was that when they had had enough practice the team would be ready to do this on a regular basis in future. If TransCanada did start building a pipeline here, the Wasps would be able to come back periodically and transport mudballs by drone to drop in the area. These squidgy payloads of dirt would contain special cultures of bacteria, including methanogens, that produce methane and other volatile chemicals. The environmental monitoring teams at the site would pick up spikes in hydrocarbon emissions, and this would inevitably bring into question the integrity of the pipeline. The Eagles would start a nationwide campaign for legal assistance, asking for lawyers to work pro bono to countermand the Energy East pipeline route, deploying the most recent scientific research on the fossil fuel industry, and all the factors that compromise oil and gas infrastructure. The Hawks would develop relationships with major energy investors, such as pension funds and insurance firms, and use public relations to highlight the risks of fossil fuel energy development, given the risks of climate change and the geological depletion of high quality resources. Nobody should be mining tar sands – the dirtiest form of energy ever devised. If TransCanada wanted to pipeline poisonous, toxic, air-damaging, climate-changing gloop all across the pristine biomes of precious Canada, the Mount Gideon teams were going to resist it in every way possible.

What the Mount Gideon teams did not know, but we know now, was that some of the activists at the camp were actually employees of the New Brunswick dynasties Irving and McCain. These families and their firms had saved the post-Confederation economy of the Maritime Provinces in the 20th Century, through vertical integration. Internally, within the Irving conglomerate, many recognised that fossil fuels had a limited future, even though some of the firms were part of the tar sands oil pipeline project. They were intending to take full advantage of the suspension of the light oil export ban from the United States for the purpose of liquefying Canadian heavy oils to make a more acceptable consumer product, as well as being something that could actually flow through pipes. They had held secret negotiations between their forestry units and the McCain family farming businesses. Research done for the companies had revealed that synthetic, carbon-neutral gas could be made from wood, grains and grasses, and that this would appeal to potential investors more than tar sands projects. They realised that if the Energy East project failed, they could step in to fill the gap in the energy market with their own brand of biomass-sourced renewables. They calculated that the potential for Renewable Gas was an order of magnitude larger than that of wind power, so they stood to profit as low carbon energy gained in popularity. Once again, in energy, big business intended to succeed, but they needed to do so in a way that was not confrontational. What better than to have a bunch of activists direct attention away from carbon-heavy environmentally-damaging energy to allow your clean, green, lean solutions to emerge victorious and virtuous ?

Notes

[1] This is a fictional, marginally futuristic account, but contains a number of factual, current accuracies.
[2] Bible, Psalm 34
[3] Bible, Judges 6-8

The first thing that struck me was that there are many items of data that are very similar between the BP and JODI Oil data; and yet there are also a good number that are significantly different – and the vast majority of these show BP reporting much higher oil consumption than JODI. This means that the definitions that BP and JODI are using for oil products consumption must correlate in many cases, when countries make their reports. But it also means that there are some understandings of oil consumption that BP has that do not have cognates in the JODI Oil reports.

The second thing that struck me was that each region in BP apart from North America is showing a total much higher than JODI Oil. Only some of the countries are specifically named in the BP report, and other countries are lumped into the bucket of “Other” within each region. Each “Other” figure is much higher in the BP report than in the JODI Oil data. Part of the reason is clearly going to be because some countries have not been reporting to JODI Oil, or not reporting reliably. For example, for South and Central America, JODI Oil data for Bermuda, Cuba, El Salvador, Haiti and Suriname are all zeroes; and JODI Oil data for Bolivia has zeroes for NOV2015 and DEC2015 (other months average at 63 KBD). But these could all be expected to be low oil products producers; so it is unclear to me where BP thinks consumption is occurring outside of the individually-named countries.

The “Other Africa” line is much higher in BP than in JODI, which looks dubious. I have not looked at this closely, but this might relate to countries such as Nigeria who produce and also consume a lot of oil.

It could be that in some cases the BP data is for all oil consumption – from national refineries and imports; whereas the JODI Oil data is for consumption from a nation’s own refinery. I would need to check this in more detail, but at first glance, the BP oil consumption data for the Middle East is much more divergent from the JODI Oil data than for other regions, and this does not make sense. I know that refinery product self-consumption is increasing in Middle East countries that are in strong economic development, but not all Middle East countries are experiencing increasing national demand, and I cannot imagine that oil products imports are so high in this region as to explain these differences between BP and JODI Oil data.

Another thing to note is that Commonwealth of Independent States (CIS) (formerly known as the “Former Soviet Union”) data divergence accounts for most of the data divergence in the “Europe & Eurasia” region; and that BP oil consumption data for the Russian Federation (which forms a part of CIS) is much higher than the data given to JODI.

I now have too many questions about how and from whom all this data is sourced, how categories of liquid hydrocarbons are delineated, and doubts about how anybody could check the reliability of any of this data. Without more information, I cannot analyse this data further; but maybe looking at oil consumption is not that illuminating. There appears to be a small and steady increase in annual oil demand and consumption over the recent period – this is indicated by both BP and JODI Oil data. The real issues for my analysis are whether oil production is capable of sustainably satisfying this demand-with-small-annual-increases, so my next step is to move to look at liquid hydrocarbons production data.

Peak conventional crude petroleum oil production is apparently here already – the only thing that’s been growing global total liquids is North American unconventional oils : tight oil – which includes shale oil in the United States of America – and tar sands oil from bitumen in Canada – either refined into synthetic crude, or blended with other oils – both heavy and light.

But there’s a problem with unconventional oils – or rather several – but the key one is the commodity price of oil, which has been low for many months, and has caused unconventional oil producers to rein in their operations. It’s hitting conventional producers too. A quick check of Section 3 “Oil data : upstream” in OPEC’s 2016 Annual Statistical Bulletin shows a worrying number of negative 2014 to 2015 change values – for example “Active rigs by country”, “Wells completed in OPEC Members”, and “Producing wells in OPEC Members”.

But in the short term, it’s the loss of uneconomic unconventional oil production that will hit hardest. Besides problems with operational margins for all forms of unconventionals, exceptional air temperatures (should we mention global warming yet ?) in the northern part of North America have contributed to a seizure in Canadian tar sands oil production – because of extensive wildfires.

Here’s two charted summaries of the most recent data from the EIA on tight oil (which includes shale oil) and dry shale gas production in the United States – which is also suffering.

Once the drop in North American unconventionals begins to register in statistics for global total liquids production, some concern will probably be expressed. Peak Oil just might be sharper and harder and sooner than some people think.

Recently, I had a very helpful telephone conversation with somebody I shall call Ben – because that’s his name, obviously, so there’s no point in trying to camoflage that fact. It was a very positive conversation, with lots of personal energy from both parties – just the sort of constructive engagement I like.

Amongst a range of other things, we were batting about ideas for what could constitute a business model or economic case for the development of Renewable Gas production – whether Renewable Hydrogen or Renewable Methane. Our wander through the highways and byways of energy markets and energy policy led us to this sore point – that the National Grid is likely to resort to “fields of diesel generators” for some of its emergency backup for the power grid in the next few years – if new gas-fired power plants don’t get built. Various acronyms you might find in this space include STOR and BM.

Now, diesel is a very dirty fuel – so dirty that it appears to be impossible to build catalytic exhaust filters for diesel road vehicles that meet any of the air pollution standards and keep up fuel consumption performance. It’s not just VW that have had trouble meeting intention with faction – all vehicle manufacturers have difficulties balancing all the requirements demanded of them. Perhaps it’s time to admit that we need to ditch the diesel fuel itself, rather than vainly try to square the circle.

The last thing we really need is diesel being used as the fuel to prop up the thin margins in the power generation network – burned in essentially open cycle plant – incurring dirty emissions and a massive waste of heat energy. Maybe this is where the petrorefiners of Great Britain could provide a Renewable Gas alternative. Building new plant or reconfiguring existing plant for Renewable Gas production would obviously entail capital investment, which would create a premium price on initial operations. However, in the event of the National Grid requiring emergency electricity generation backup, the traded prices for that power would be high – which means that slightly more expensive Renewable Gas could find a niche use which didn’t undermine the normal economics of the market.

If there could be a policy mandate – a requirement that Renewable Gas is used in open cycle grid-balancing generation – for example when the wind dies down and the sun sets – then we could have fields of Renewable Gas generators and keep the overall grid carbon emissions lower than they would otherwise have been.

Both Ben and I enjoyed this concept and shared a cackle or two – a simple narrative that could be adopted very easily if the right people got it.

So I’m in the wonderfully atmospheric wood-panelled Room 102 at 30 Russell Square in Bloomsbury trying to talk engineering to mostly business and communications students. Which is a challenge in itself. Yet I’m also trying not to do too much talking, but encourage the other people in the room to play with the information I’m presenting and do their own thinking.

It’s all about energy transition – or “Energy Change” – as I term it – that I argue is an essential response to Climate Change. I also argue that Energy Change is an essential response to discontinuities and emerging fractures in the current fossil fuel-dominated global energy system and the global economy.

But mostly I argue with a fair amount of positive personal energy that we already have all the technologies we need to move towards a very low carbon and 100% renewable energy system, where low carbon gas backs up variable renewable electricity generation.

During the discussion after my presentation, where the room became full of buzzing brain power, I ask people to break out into small groups to answer these not-too-simple policy questions :-

Q1. Can you design a policy support mechanism
for Renewable Gas that doesn’t involve subsidies
in any area of : electricity generation, heating &
cooling, transportation or energy storage ?

Q2. In whose short-term and long-term
interests would it be to begin to provide
Renewable Gas ? What should their strategy be ?

Q3. What barriers to the growth of Renewable
Gas production do you think there will be ?

There were some very interesting answers given to the room at the end before we had to open celebration bottles to complete the positive cheer. And then, of course, after all that jollity, I had to take in a pint of dry cider and some hot potato chips at the pub with my colleague Dr Paul Elsner and engage in a conversation, the upshot of which is that I now have a massive “to do” list.

I have had the great fortune to meet another student of the Non-Science of Economics who believes most strongly that Energy is only a sub-sector of the Holy Economy, instead of one of its foundations, and doesn’t understand why issues with the flow of commodities (which include energy resources) into the system is critical to the survival of the global economy, and that the growth in the Services Industries and Knowledge Economy cannot compensate for the depletion of freshwater, fossil fuels and other raw resources.

This person believes in Technology, as if it can fly by itself, without seeming to understand how Technological Innovation is really advanced by state investment – a democracy of focus. This otherwise intelligent learner has also failed to grasp, apparently, that the only way that the Economy can grow in future is through investment in things with real value, such as Energy, especially where this investment is essential owing to decades of under-investment precipitated by privatisation – such as in Energy – investment in both networks of grids or pipes, and raw resources. And this from somebody who understands that developing countries are being held back by land grab and natural resource privatisation – for example ground water; and that there is no more money to be made from property investment, as the market has boomed and blown.

How to burst these over-expanded false value bubbles in the mind ? When I try to talk about the depletion of natural resources, and planetary boundaries, people often break eye contact and stare vacantly out of the nearest window, or accept the facts, but don’t see the significance of them. Now this may be because I’m not the best of communicators, or it may be due to the heavy weight of propaganda leading to belief in the Magical Unrealism always taught in Economics and at Business Schools.

Whatever. This is where I’m stuck in trying to design a way to talk about the necessity of energy transition – the move from digging up minerals to catching the wind, sunlight and recycling gases. If I say, “Look, ladies and laddies, fossil fuels are depleting”, the audience will respond with “where there’s a drill, there’s a way”. As if somehow the free market (not that a free market actually exists), will somehow step up and provide new production and new resources, conjuring them from somewhere.

What are arguments that connect the dots for people ? How to demonstrate the potential for a real peak in oil, gas, coal and uranium production ? I think I need to start with a basic flow analysis. On the one side of the commodity delivery pipeline, major discoveries have decreased, and the costs of discovery have increased. The hidden underbelly of this is that tapping into reservoirs and seams has a timeline to depletion – the point at which the richness of the seam is degraded significantly, and the initial pressure in the well or reservoir is reduced to unexploitable levels – regardless of the technology deployed. On the other end of the commodities pipeline is the measure of consumption – and most authorities agree that the demand for energy will remain strong. All these factors add up to a time-limited game.

Oh, you can choose to believe that everything will continue as it always seems to have. But the Golden Age of Plenty is drawing to a close, my friend.

For example, the report states in Section 3.40 that : “…measures to protect and diversify sources of [energy] supply will become increasingly important, including the new Southern Corridor pipeline, US liquid natural gas (LNG) exports, further supplies of Australian LNG, and increased supply from Norway and North Africa.”

I have already addressed my recommendation that the writers of this report should be more careful to distinguish between Liquefied Natural Gas (LNG) which is a methane-rich product that can substitute for Natural Gas; and Natural Gas Liquids (NGLs) which is a methane-poor product that cannot substitute for Natural Gas.

However, assuming that the writers of the report are talking about cryogenically stored and transported Natural Gas-sourced energy gases, there is a problem in assuming that the United States will be exporting any large amounts of LNG to Europe any time soon. In fact, there are several problems.

Just because the business and political press have been touting the exciting prospect of US LNG exports, doesn’t mean that the data backs up this meme.

All of which adds up to a puzzled look on my face. How can the British Government reasonably expect the commencement of significant quantities of American LNG exports to arrive in the UK ? The only reason they believe this is because there has been American propaganda, promulgated through media of all kinds, for the last five or so years, to convince the world that the USA can achieve greater energy independence through the “explosion” in shale gas production.

It’s a story told by many successive US Governments – that the US can achieve greater energy independence, but the reality is very, very different.

The UK Government should not believe any narrative of this nature, in my view, nor include it in national security analyses.

The energy “trilemma” is the dilemma of three dimensions : how to decarbonise the energy system, whilst continuing to provide affordable energy to consumers, at a high security of supply. The unspoken fourth dimension is that of investment : just who is going to invest in British energy, particularly if green energy booster subsidies and regulatory measures are binned ? The UK Government have in the past few years believed that they need to support new investment in new technologies, but it looks likely that this drive is about to lose all its incentives.

At last week’s Energy Live News conference, Andrea Leadsom, Minister of State for Energy at the UK Government’s Department of Energy and Climate Change (DECC), headed up the morning, with a bit of a lead in from ELN Editor Sumit Bose. He said that continuing challenges arose from the optimisation of balancing reserves and demand side management in electricity generation. He said that policy had perhaps swung away from the projection of 100% electrification of British energy, as this would require at least 15% more committed capital expenditure – although there would be savings to be had in operational expenditure. He also said that there is an ongoing budgetary conflict going on in government departments about the public money available to spend on investment in infrastructure (including that for energy). Obviously, the announcement of the Infrastructure Commission is going to help in a number of areas – including reaching for full electrification of the railways – a vital project. Then he introduced the Minister.

Andrea Leadsom said, “This government is determined to resolve the energy trilemma, decarbonising at the lowest cost to the consumer whilst keeping the lights on. In the past we did tend to have crazes on different technologies….”. At this point I wondered if she included nuclear power in that set of crazes, but her later remarks confirmed she is still entrenched in that fad.

Leadsom said, “There’s been a big move to renewable energy technologies, and quite rightly too. We need a wide diversity of electricity sources. We need to try and improve the new nuclear programme…”, at which point I thought to myself, “Good luck with that !”. She said, “Renewable energy has trebled. We need [to fund] that transition from unabated coal, [turn on to] gas and renewables. [But] as we saw yesterday – there is an intermittency of renewables.”

Andrea Leadsom was referring to the previous day, when National Grid has issued their first call for surplus top-up power generation since 2012. Owing to a confluence of weather systems over the UK, the atmosphere was becalmed, and wind power output was close to zero. However, this had already been predicted to happen. The lack of wind power was not the problem.

The problem lay in two other areas. Of the completely inflexible nuclear power plants, three generators were out of action for scheduled maintenance (Hunterston B, Reactor 3; Heysham 1, Reactor 1 and Hartlepool Reactor 1). And so when two coal-fired power plants which normally would have been operational were out of action, and one failed apparently between 12:45pm and 12:51pm (Eggborough, Fiddlers and Rugeley according to various sources) dropping approximately 640 megawatts (MW) out of the system (according to BM Reports data), National Grid had to resort to elements of their balancing “toolkit” that they would not normally use.

The operators generating for the National Grid were able to ramp up Combined Cycle Gas Turbine (CCGT), and various large electricity users with special arrangements with National Grid were stopped using power. By around 18:00 6pm the emergency was over, with peak demand for the evening levelling off at around 48 gigawatts (GW).

Although National Grid handled the problem well, there was a serious risk of blackouts, but again, not because of wind power.

If during the period of supply stress, one of the nuclear power plants had suddered an outage, that would have created the “nightmare scenario”, according to Peter Atherton, from Jefferies, quoted in The Guardian newspaper. The reason for this is that the nuclear power plants are large generators, or “baseload” generators. They have suffered from problems of unreliability over the recent years, and whenever they shutdown, either in a planned or an unplanned manner, they cause the power grid a massive headache. The amount of power lost is large, and there’s sometimes no guarantee of when the nuclear generation can be restored. In addition, it takes several hours to ramp up replacement gas-fired power plants to compensate for the power lost from nuclear.

Yes, Andrea Leadsom, more renewable energy is essential to meet decarbonisation goals. Yes, Andrea Leadsom, renewable energy technologies have an inherent intermittency or variability in their output. No, Andrea Leadsom, National Grid’s problems with power generation during the winter months is not caused by wind power on the system – wind power is providing some of the cheapest resources of electricity. No, Andrea Leadsom, insecurity in Britain’s power supply is being caused by ageing nuclear and coal power plants, and the only way to fix that is to create incentives to develop a plethora of differently-scaled generation facilities, including many more decentralised renewable energy utilities, flexible top-up backup gas-fired power plants, including Combined Heat and Power town-scale plants, and Renewable Gas production and storage facilities.

Everything in the UK world of energy hit a kind of slow-moving nightmare when the Department of Energy and Climate Change stopped replying to emails a few months ago, claiming they were officially ordered to focus on the “Spending Review” – as known as “The Cuts” – as ordered by George Osborne, Chancellor of Her Majesty’s Treasury.

We now know that this purdah will be terminated on 25th November 2015, when various public announcements will be made, and whatever surprises are in store, one thing is now for certain : all grapevines have been repeating this one word regarding British energy policy : “reset”.

Some are calling it a “soft reset”. Some are predicting the demise of the entire Electricity Market Reform, and all its instruments – which would include the Capacity Auction and the Contracts for Difference – which would almost inevitably throw the new nuclear power ambition into a deep dark forgettery hole.

A report back from a whispering colleague regarding the Energy Utilities Forum at the House of Lords on 4th November 2015 included these items of interest :-

“…the cost of battery power has dropped to 10% of its value of a few years ago. National Grid has a tender out for micro-second response back up products – everyone assumes this is aimed at batteries but they are agnostic … There will be what is called a “soft reset” in the energy markets announced by the government in the next few weeks – no one knows what this means but obviously yet more tinkering with regulations … On the basis that diesel fuel to Afghanistan is the most expensive in the world (true), it has to be flown in, it has been seriously proposed to fly in Small Modular Nuclear reactors to generate power. What planet are these people living on I wonder ? … A lot more inter connectors are being planned to UK from Germany, Belgium Holland and Norway I think taking it up to 12 GWe … ”

Alistair Phillips-Davies, the CEO of SSE (Scottish and Southern Energy), took part in a panel discussion at Energy Live News on 5th November 2015, in which he said that he was expecing a “reset” on the Electricity Market Reform (EMR), and that the UK Government were apparently focussing on consumers and robust carbon pricing. One view expressed was that the EMR could be moved away from market mechanisms. In other discussions, it was mentioned that the EMR Capacity Market Auction had focussed too much on energy supply, and that the second round would see a wider range of participants – including those offering demand side solutions.

Energy efficiency, and electricity demand profile flattening, were still vital to get progress on, as the power grid is going to be more efficient if it can operate within a narrower band of demand – say 30 to 40 GW daily, rather than the currently daily swing of 20 to 50 GW. There was talk of offering changing flexible, personal tariffs to smooth out the 5pm 17:00 power demand peak, as price signalling is likely to be the only way to make this happen, and comments were made about how many computer geeks would be needed to analyse all the power consumption data.

The question was asked whether the smart meter rollout could have the same demand smoothing effect as the Economy 7 tariff had in the past.

The view was expressed that the capacity market had not provided enough by way of long-term price signals – particularly for investment in low carbon energy. One question raised during the day was whether it wouldn’t be better just to set a Europe-wide price on carbon and then let markets and the energy industry decide what to put in place ?

So, in what ways could the British Government “reset” the Electricity Market Reform instruments in order to get improved results – better for pocket, planet and energy provision ? This is what I think :-

1. Keep the Capacity Mechanism for gas

The Capacity Mechanism was originally designed to keep efficient gas-fired power plants (combined cycle gas turbine, or CCGT) from closing, and to make sure that new ones were built. In the current power generation portfolio, more renewable energy, and the drive to push coal-fired power plants to their limits before they need to be closed, has meant that gas-fired generation has been sidelined, kept for infrequent use. This has damaged the economics of CCGT, both to build and to operate. This phenomenon has been seen all across Europe, and the Capacity Market was supposed to fix this. However, the auction was opened to all current power generators as well as investors in new plant, so inevitably some of the cash that was meant for gas has been snaffled up by coal and nuclear.

2. Deflate strike prices after maximum lead time to generation

No Contracts for Difference should be agreed without specifying a maximum lead time to initial generation. There is no good reason why nuclear power plants, for example, that are anticipated to take longer than 5 years to build and start generating should be promised fixed power prices – indexed to inflation. If they take longer than that to build, the power prices should be degressed for every year they are late, which should provide an incentive to complete the projects on time. These projects with their long lead times and uncertain completion dates are hogging all the potential funds for investment, and this is leading to inflexibility in planning.

3. Offer Negative Contracts for Difference

To try to re-establish a proper buildings insulation programme of works, projects should be offered an incentive in the form of contracts-for-energy-savings – in other words, aggregated heat savings from any insulation project should be offered an investment reward related to the size of the savings. This will not be rewarding energy production, but energy use reduction. Any tempering of gas demand will improve the UK’s balance of payments and lead to a healthier economy.

4. Abandon all ambition for carbon pricing

Trends in energy prices are likely to hold surprises for some decades to come. To attempt to set a price on carbon, as an aid to incentivising low carbon energy investment is likely to fail to set an appropriate investment differential in this environment of general energy pricing volatility. That is : the carbon price would be a market signal lost in a sea of other effects. Added to which, carbon costs are likely to be passed on to energy consumers before they would affect the investment decisions of energy companies.

Status-checking questions. I’m sure we all have them. I certainly do. Several times a week, or even day, I ask myself two little questions of portent : “What am I doing ?” and “Why am I here ?”. I ask myself these questions usually because my mind’s wandered off again, just out of reach, and I need to call myself to attention, and focus. I ask these little questions of myself when I do that thing we all do – I’ve set off with great purpose into another room, and then completely forgotten why I went there, or what I came to find or get. I also use these forms of enquiry when I’m at The Crossroads of Purpose – to determine what exactly it is I’m deciding to aim for. What are my goals this day, week, month, age ? Can I espy my aims, somewhere on the horizon ? Can I paddle labouriously towards them – against the tide – dodge/defeat the sharks ? Can I muster the will to carry this out – “longhauling it” ?

I’ve spent a long time writing a book, which I’m sure to bore everybody about for the next aeon. My intention in writing the book was to stimulate debate about what I consider to be the best direction for balanced energy systems – a combination of renewable electricity and Renewable Gas. I wanted to foster debate amongst the academics and engineers who may be my peers, certainly, hopefully providing a little seed for further research. Hopefully also having a small influence on energy policy, perhaps, or at least, getting myself and my ideas asked to various policy meetings for a little airing. But, if I could in some way, I also wanted to offer a bit of fizz to the internal conversations of companies in the energy sector. You see, it may be obvious, or it may not be, but action on climate change, which principally involves the reduction in the mining, drilling and burning of fossil fuels, principally also involves the co-operation of the fossil fuel extraction companies. Their products are nearly history, and so it must be that inside the headquarters of every transnational energy giant, corporate heads are churning through their options with a very large what-if spoon.

She writes, “The ambit claims know no bounds. Who else would ask for $89,000,000,000,000? If the evil “more developed” nations pay for their carbon sins, the bill for those 1.3 billion people works out at $70,000 per person by 2030 (babies included).”

“The global economy will require substantial investments in infrastructure as the population and the middle class grow. An estimated US$89 trillion of infrastructure investment will be required through 2030, based on data from the International Energy Agency (IEA), the Organisation for Economic Co-operation and Development (OECD), and analysis for the Commission (see Figure 1). This is chiefly investment in energy and cities. This estimate for the required investment is before accounting for actions to combat climate change.”

That’s before accounting for actions to combat climate change, Ms Nova. Before. I know it’s probably clanging against your internal cognitive fences, but the fact is, the world needs to spend a heap of capital in the next 20 to 30 years reviving, replacing and renewing energy systems infrastructure. That spending has to happen regardless of whether it’s low carbon spending.

And let’s read the note on Figure 1 more carefully :-

“INCLUDING OPERATING EXPENDITURES WOULD MAKE A LOW-CARBON TRANSITION EVEN MORE FAVOURABLE LEADING TO A FURTHER REDUCTION OF US$5 TRILLION, FOR OVERALL POTENTIAL SAVINGS OF US$1 TRILLION”

So, Jo Nova, the world will actually be better off if it decides to make all new energy expenditure low carbon.

Volatile crude petroleum oil commodity prices over the last decade have played some undoubted havoc with oil and gas company strategy. High crude prices have pushed the choice of refinery feedstocks towards cheap heavy and immature gunk; influenced decisions about the choices for new petrorefineries and caused ripples of panic amongst trade and transport chiefs : you can’t keep the engine of globalisation ticking over if the key fuel is getting considerably more expensive, and you can’t meet your carbon budgets without restricting supplies.

Low crude commodity prices have surely caused oil and gas corporation leaders to break out into the proverbial sweat. Heavy oil, deep oil, and complicated oil suddenly become unprofitable to mine, drill and pump. Because the economic balance of refinery shifts. Because low commodity prices must translate into low end user refined product prices.

There maybe isn’t an ideal commodity price for crude oil. All the while, as crude oil commodity prices jump around like a medieval flea, the price of Natural Gas, and the gassy “light ends” of slightly unconventional and deep crude oil, stay quite cheap to produce and cheap to use. It’s a shame that there are so many vehicles on the road/sea/rails that use liquid fuels…all this is very likely to change.

Shell appear to be consolidating their future gas business by buying out the competition. Hurrah for common sense ! The next stage of their evolution, after the transition of all oil applications to gas, will be to ramp up Renewable Gas production : low carbon gas supplies will decarbonise every part of the economy, from power generation, to transport, to heating, to industrial chemistry.

This is a viable low carbon solution – to accelerate the use of renewable electricity – wind power and solar principally – and at the same time, transition the oil and gas companies to become gas companies, and thence to Renewable Gas companies.

So, this is the second slide from my presentation at Birkbeck, University of London, last week.

When making an argument, it is best to start from consensus and well-accredited data, so I started with government analysis of the energy sector of the economy in the United Kingdom. Production of Natural Gas in the UK is declining, and imports are rising.

I did not go into much detail about this chart, but there is a wealth of analysis out there that I would recommend people check out.

Despite continued investment in oil and gas, North Sea production is declining, and it is generally accepted that this basin or province as a whole is depleting – that is – “running out”.

The summary concluded with the estimate of remaining recoverable hydrocarbons from the UK Continental Shelf (offshore) resources would be between 11.1 and 21 billion barrels of oil equivalent (bboe).

Other data in the report showed estimates of cumuluative and annual oil production :-

billion barrels of oil equivalent

Cumulative production

Annual production

To date to end 2012

41.3

0.6 (in 2012)

To date to end 2012

41.8

0.5 (in 2013)

Additional production 2013 to 2030

7.0

0.44 (average 2014 to 2030)

Additional production 2013 to 2040

9.1

0.21 (average 2031 to 2040)

Additional production 2013 to 2050

10.4

0.13 (average 2041 to 2050)

Another source of estimates on remaining oil and gas resources, reserves and yet-to-find potential is from the Wood Review of 2014 :-

billion barrels of oil equivalent

Low case

Mid-case

High case

DECC reference

12

22

35

Wood Review

12

24

So it’s clear that British oil and gas production is in decline, and that also, reserves and resources to exploit are depleting. The Wood Review made several recommendations to pump up production, and maximise the total recoverable quantities. Some interpreted this as an indication that good times were ahead. However, increased production in the near future is only going to deplete these resources faster.

“The North sea is a very mature oil and gas province and it will inevitably go through a decline. It peaked in 1999 at around 2.9 millions barrels per day and our projections are that it will be half a million barrels in 2035”.

In the last couple of years I have researched and written a book about the technologies and systems of Renewable Gas – gas energy fuels that are low in net carbon dioxide emissions. From what I have learned so far, it seems that another energy world is possible, and that the transition is already happening. The forces that are shaping this change are not just climate or environmental policy, or concerns about energy security. Renewable Gas is inevitable because of a range of geological, economic and industrial reasons.

I didn’t train as a chemist or chemical process engineer, and I haven’t had a background in the fossil fuel energy industry, so I’ve had to look at a number of very basic areas of engineering, for example, the distillation and fractionation of crude petroleum oil, petroleum refinery, gas processing, and the thermodynamics of gas chemistry in industrial-scale reactors. Why did I need to look at the fossil fuel industry and the petrochemical industry when I was researching Renewable Gas ? Because that’s where a lot of the change can come from. Renewable Gas is partly about biogas, but it’s also about industrial gas processes, and a lot of them are used in the petrorefinery and chemicals sectors.

In addition, I researched energy system technologies. Whilst assessing the potential for efficiency gains in energy systems through the use of Renewable Electricity and Renewable Gas, I rekindled an interest in fuel cells. For the first time in a long time, I began to want to build something – a solid oxide fuel cell which switches mode to an electrolysis unit that produces hydrogen from water. Whether I ever get to do that is still a question, but it shows how involved I’m feeling that I want to roll up my sleeves and get my hands dirty.

Even though I have covered a lot of ground, I feel I’m only just getting started, as there is a lot more that I need to research and document. At the same time, I feel that I don’t have enough data, and that it will be hard to get the data I need, partly because of proprietary issues, where energy and engineering companies are protective of developments, particularly as regards actual numbers. Merely being a university researcher is probably not going to be sufficient. I would probably need to be an official within a government agency, or an industry institute, in order to be permitted to reach in to more detail about the potential for Renewable Gas. But there are problems with these possible avenues.

You see, having done the research I have conducted so far, I am even more scornful of government energy policy than I was previously, especially because of industrial tampering. In addition, I am even more scathing about the energy industry “playing both sides” on climate change. Even though there are some smart and competent people in them, the governments do not appear to be intelligent enough to see through expensive diversions in technology or unworkable proposals for economic tweaking. These non-solutions are embraced and promoted by the energy industry, and make progress difficult. No, carbon dioxide emissions taxation or pricing, or a market in carbon, are not going to make the kind of changes we need on climate change; and in addition they are going to be extremely difficult and slow to implement. No, Carbon Capture and Storage, or CCS, is never going to become relatively affordable in any economic scenario. No, nuclear power is too cumbersome, slow and dodgy – a technical term – to ever make a genuine impact on the total of carbon emissons. No, it’s not energy users who need to reduce their consumption of energy, it’s the energy companies who need to reduce the levels of fossil fuels they utilise in the energy they sell. No, unconventional fossil fuels, such as shale gas, are not the answer to high emissions from coal. No, biofuels added to petrofuels for vehicles won’t stem total vehicle emissions without reducing fuel consumption and limiting the number of vehicles in use.

I think that the fossil fuel companies know these proposals cannot bring about significant change, which is precisely why they lobby for them. They used to deny climate change outright, because it spelled the end of their industry. Now they promote scepticism about the risks of climate change, whilst at the same time putting their name to things that can’t work to suppress major amounts of emissions. This is a delayer’s game.

Because I find the UK Government energy and climate policy ridiculous on many counts, I doubt they will ever want me to lead with Renewable Gas on one of their projects. And because I think the energy industry needs to accept and admit that they need to undergo a major change, and yet they spend most of their public relations euros telling the world they don’t need to, and that other people need to make change instead, I doubt the energy industry will ever invite me to consult with them on how to make the Energy Transition.

I suppose there is an outside chance that the major engineering firms might work with me, after all, I have been an engineer, and many of these companies are already working in the Renewable Gas field, although they’re normally “third party” players for the most part – providing engineering solutions to energy companies.

Because I’ve had to drag myself through the equivalent of a “petro degree”, learning about the geology and chemistry of oil and gas, I can see more clearly than before that the fossil fuel industry contains within it the seeds of positive change, with its use of technologies appropriate for manufacturing low carbon “surface gas”. I have learned that Renewable Gas would be a logical progression for the oil and gas industry, and also essential to rein in their own carbon emissions from processing cheaper crude oils. If they weren’t so busy telling governments how to tamper with energy markets, pushing the blame for emissions on others, and begging for subsidies for CCS projects, they could instead be planning for a future where they get to stay in business.

The oil and gas companies, especially the vertically integrated tranche, could become producers and retailers of low carbon gas, and take part in a programme for decentralised and efficient energy provision, and maintain their valued contribution to society. At the moment, however, they’re still stuck in the 20th Century.

I’m a positive person, so I’m not going to dwell too much on how stuck-in-the-fossilised-mud the governments and petroindustry are. What I’m aiming to do is start the conversation on how the development of Renewable Gas could displace dirty fossil fuels, and eventually replace the cleaner-but-still-fossil Natural Gas as well.

The UK Government’s Electricity Market Reform (EMR) is a moving feast, or “trough”, if you are of the opinion that any state subsidy is a subsidy too far. My, how people complained and complained about the Renewables Obligation (RO), perhaps one of the world’s best stimuli for pushing forward wind power development. Yes, some rich engineering firms and rich landowners got richer on the back of the RO. What do you expect ? The wealthy always leverage their capital. But at least the RO has produced some exceptional wind power generation numbers. In the period 2017 to 2018 however, the RO is set to be staged down and replaced by several elements in the EMR, most notably, the CfD or Contracts for Difference, otherwise affectionately and quite inaccurately described as the FiT CfD – Feed-in Tariff Contracts for Difference.

The basic plan for the CfD is to guarantee to new electricity generators, or old generators building new plant, a definite price on power sold, in order to ensure they can get debt and equity invested in their projects. However, this is a huge state intervention and potentially entirely scuppers the efforts to create a market in electricity. More dangerously, although the CfD is supposed to encourage the freeing up of capital to support new energy investment, it might fail in that, at least in the short-term, and it may even fail to make capital cheaper. This is due to the new kinds of risk associated with the CfD – particularly because of the long lead time from auction to allocation, and the cap on allocations. The CfD is designed to create project failures, it seems.

I recently attended an event hosted at the Queen Elizabeth II Conference Centre in Westminster in London, called Energy4PowerLive 2014 and managed by GMP. The first session I attended was in the RenewablesLive 2014 stream, and featured a panel discussion between Andrew Buglass from Royal Bank of Scotland (RBS), Philip Bazin of Triodos and Steve Hunter, Investment Director of Low Carbon.

What follows is not verbatim, and is based on my handwritten notes, and my handwriting is appalling, so that sometimes, even I cannot read it.

[You may have an interest in the actions of] RBS [heckle from the audience, “We own it !”]. We built our first renewable energy project in 1991 – an onshore wind turbine. Now we [have helped] finance 9 gigawatts of renewable energy. I have 15 minutes – only possible to scratch the surface of CfDs [Contracts for Difference – a subsidy under the UK Government Department of Energy and Climate Change (DECC) Electricity Market Reform (EMR))]. The EMR journey has been a very long one – four years. We have offered advice to the government – about the bankability of the policy. DECC have a different policy perspective – they are going over here [in this direction] whether or not… [Their aim was to] encourage new sources of investment debt and equity, [currently] not here in the UK. […] Matt Hancock, new [energy] minister […] £115 [billion ?] […]. Half of £100 billion needed by end of decade. The EMR framework is [intended] to bring in new sources of debt and equity – its ability to track that into the market. I’m not going to review whether the EMR will be successful. It’s a “Nought to Sixty” question [reference to how quickly it takes for cars to accelerate], how quickly is capital going to be delivered [getting up and running]. There will be a big step up in terms of work […] how are different counterparties [countersigning parties in the CfD contracts] responding ? Now is the time to deliver on the [practical economics] for those to decide whether to invest or not. Need to engage the ratings agencies – getting debt from bond markets – to convince Standard and Poor etc to convince […] The first projects are going to take a long time – cutting their teeth. Cost, availability, terms of debt. The risks that will [come into play] :

A. OFFTAKE RISK – BASIS RISK
[At the start of the EMR discussions] we highlighted that small generators found it hard to get PPAS [Power Purchase Agreements]. With the CfDs “lender of last resort” “offtaker of last resort” […] may support less strong balance sheets for PPAs. Great – because we need a lot more liquidity in PPAs. [However] the basis risks on the strike price compared to the reference price – if this is [changed, different] – a concern about whether they might be matching in the middle [and so conferring no benefit to having arranged the CfD]].

B. WHOLESALE PRICE RISK
In offshore wind – wild – the economics of generating. In onshore wind power, the wholesale price has less of a way to fall [because of many years of learning and maturing of supply chains etc].

C. INDEX INFLATION RISK
The CfDs are to be linked to CPI [Consumer Price Index] rather than the RPI [Retail Price Index]. This may seem like a not very important difference – but at the moment you cannot hedge against the CPI. […] we recommend RPI – linked to lock in. Can’t do that with CPI.

D. FORCE MAJEURE RISK
[Risk] especially during construction. The CfD does not pick up during construction – need to see [how this pans out].

E. CHANGE IN LAW (CIL) RISK
Twenty pages of the CIL clause – doesn’t seem to give you much protection – what is a “foreseeable change in law” ? Unless you’re a big utility you will not have been tracking [policy and legislation] for the last ten years. Big risk ? In the RO [Renewables Obligation], CIL risk was set to the offtaker. Law firms are going to really agonise [over this in the CfD].

F. LIFETIME MANAGEMENT RISK
Risk relating to managing CfD contract during its lifetime. There is a risk from the termination of a CfD – more than in the RO. May need to do more work to keep lender involved to manage termination risk.

Leads to a gloomy approach – in banking paying back on time is good – anything else is bad.

The EMR has cross-party support, but this is the most interventionist approach since the CEGB (Central Electricity Generating Board market). The politicians are saying “no, no, we’d never change anything” – from three parties. It would help if there were a public statement on that (I get calls about “too many turbines”). Initial projects will probably take longer to start than [under] RO. Collectively fund pragmatic solutions.

Triodos was established in 1980, and started in the UK in 1995 with the acquisition of Mercury […] Our portfolio in the UK is still relatively small. Over a third of the £500 million is in renewable energy. Our investment […] basis of positive social and environmental outcomes. […] Core lending of £1 to £15 million finance […] construction […] and up to 15 years [on loan repayment]. Smaller developers – best fit. The bank is almost becoming part of the supply chain in the bidding process. Give a forward fixed rate of interest. We’ve had to think about how we provide this derivative. Discussions with PPA providers. Feeling that most a lot of new players. The whole rush around CfD was quite unhelpful. We haven’t been engaging with any bidders for this round [of CfDs]. Our customers are small generators or community groups. Smaller projects are risk-averse and would [probably] use the RO instead of the CfD [for now]. These markets are going to find this new structure [offputting]. Not ideal if you’re a professional investor. [Andrew has explained the risks well] The biggest one for me is the risk of failing to achieve your LONGSTOP DATE [failure to start electricity generation by an agreed date], which would risk a termination [of the CfD subsidy agreement. This would destroy the economics of the whole project and therefore the investment]. What protections do you have as a sub-contractor ? Another point is about wayleaves. [If you can’t get your wayleaves in time…] Fundamentally, the [CfD] mechanism is bankable. [However] in trying to fix a problem it [may] have created a total mess. Don’t know if more capital will be going into projects.

[Our business is in] Solar PV, Onshore wind, CSP in the Mediterranean area. We get there when project developer is doing land deals. We have a cradle-to-grave perspective. Land planning and grid access are major risks [and the guarantee of biomass feedstock for a biomass project]. The WHOLESALE POWER PRICE RISK – someone needs to take it. Your view depends on your equity horizon. For us, the two big changes [from the RO] are the introduction of the ALLOCATION RISK and the removal of the power price risk. Don’t know the budget for allocation. Only know one month before the [CfD] auction ! The government has not released [a budget] for “emerging technology”. Timing : doesn’t really work for solar. The idea of CfD versus RO for solar will not work. [It’s all down to the project lifecycle] – you could be waiting 14 or 15 months for a CfD allocation after making a bid, but grid connection deals are now closing in [at around 12 months – if you do not take up your grid connection permission, you will lose it]. At the moment there is no competition between technologies. Is there enough CfD set aside for offshore wind projects ? Yes. If CfDs are intended to deliver technology-neutral [energy mix] – it doesn’t yet. The REFERENCE PRICES for me are the significant risk. This is entirely new for CfDs. Because the CfD intended to bring lower cost of capital – there is an implication for return [on investment] to the investor. Government will set [the reference prices]. Government just released [for some technologies] – decreased [in a forward period]. The Government may have a very different view on forward power prices… These reference prices come out of the air [there seems to be no basis for them]. When is final not final ? When it comes from DECC. If consider 2018/2019 September, the tightest budget, you could afford 1,000 MW of offshore, [if there is a change in the reference price] you could only afford 700 MW. In the TEC Register from National Grid – download this – there is 1,000 to 1,200 MG in the pipeline onshore. If I was a wind developer with [grid] connection dates after the end of the RO, you can bet I’ve already bid [for a CfD allocation] already. The political risk of changing the RO. May be a small amount of solar – but anyway it’s too expensive. If the CfD is only to support onshore wind power – is it achieving its goals ? There will almost certainly be some modification [to the CfD or the reference prices ?]. Transparency ? Oversupply ? [Oversight ?] of setting reference prices. Increase in frequency of the CfD auction would be helpful. Would give developers more time to bid. Technologies like solar PV that could deliver large savings… If no large solar is built… They could put a minimum in [for the subsidy allocated to each technology] – more positive. CfD represents long-term support. If the industry drives down the cost of renewable energy, CfD gives us an infill fix on revenue. It will give that certainty to get debt [and equity] in. It may be the support mechanism we need in the long-term. It could be the support mechanism we need for renewable energy…

How do we get things changed in a democracy ? The model of political campaigning that has been established over the last century is failing us. In the past, if there was a problem, a small group of people could create a fuss about it, march some placards to somewhere relevant, write some letters, talk to some dignitaries, chain themselves to some railings, occupy a lobby, get some press, and after some years, maybe, get something done.

These days there are just too many complaints for them all to be heard. Philanthropic, charitable and political messages crowd the stage. In this age of social media, the campaign metaphor has been replaced by a ladder of concern. Concern is expressed. Hopefully others will find that they too are sufficiently concerned, and reflect that concern through some medium. And slowly, it is hoped, this concern climbs the ladder of attention, until it is visible, audible. The entitled and endowed middle classes catch the concern, and repeat it. Lots of emails fly. George Monbiot writes about it in The Guardian. Some speeches are made at serious meetings. Angelina Jolie is invited to grace a conference. And then, hopefully, this concern hits the people who have some kind of leverage over the problem, and they act.

Action is almost guaranteed if the concern is the result of a specific outrage, committed by a specific person or group, and has a specific solution. But otherwise, who knows ? How universal and impactful does a concern need to be before it gets acted upon ? And surely some things don’t need campaigns, because the governments already know enough about problems such as people trafficking, slavery, animal welfare, crime and torture ? After all, things such as prostitution and illegal drug trade are included in national economic statistics.

I took public transport today in London and I was doused in outrage pouring from advertisements asking for charitable giving to prevent the inhuman practice of Female Genital Mutilation (FGM). As I read these appeals, I felt two overwhelming sensations – one of intense anger that children are being permanently injured because of insane and unjustifiable, hateful beliefs about female sexuality. And a second feeling of dragging despair that giving a small donation every month to this organisation would have very little impact on abusive culture, which leads to many forms of violation, not just the unimaginably painful and destructive incision and even resection of a child’s clitoris and the sewing together of her labia, leading to permanent nerve damage, lasting wounds, loss of sexual function, complications from incontinence, ruined relationships, injuries from sexual intercourse, and serious medical risks during childbirth, and possibly the need for reconstructive surgery.

Switch to BBC News. Roger Harrabin reports that “The UK’s chief scientist says the oceans face a serious and growing risk from man-made carbon emissions. […] Sir Mark Walport warns that the acidity of the oceans has increased by about 25% since the industrial revolution, mainly thanks to manmade emissions. […] He told BBC News: “If we carry on emitting CO2 [carbon dioxide] at the same rate, ocean acidification will create substantial risks to complex marine food webs and ecosystems.” […] The consequences of acidification are likely to be made worse by the warming of the ocean expected with climate change, a process which is also driven by CO2.”

Media Lens Editors reported this piece. My reaction was – who would be paying attention to this ? This is not the “dangerous climate change comes from global warming” story, this is the “other” carbon problem, the decimation of marine productivity and the whole pyramid of life, resulting from increasing levels of dissolved carbon dioxide in seawater because of higher levels of carbon dioxide in the air. The overwhelmingly major causes of this problem are irrefutably and definitely fossil fuel combustion, and its seriousness is hard to deny, even though Roger Harrabin attempts to make light of it by devoting column inches to a laboratory crab who isn’t getting with the programme.

Ocean acidification is a concern that shouldn’t get lost in amongst other concerns. It should be paid serious levels of attention. And not just by middle class philanthropists who work for non-governmental organisations and charities. And yet, cursory analysis of the segmentation of the population who treat BBC News as a main and trusted information source may suggest that the only readers who would act on this piece are exactly these middle class charity staff, or at a push, retired middle class charity staff.

My Media Lens comment was, “Right expert. Right message. Wrong audience. Wrong medium. The UK Government’s chief scientist. OK. Good. Ocean acidification. OK. Good. No quibbles about whether or not extra carbon dioxide in the atmosphere is a real problem or not (as known as “climate change” or “global warming”, which is real by the way). The BBC News. Wrong medium. Wrong audience. The only people going to listen to this are those who already know about the problem but are still as powerless to act as they were yesterday. The UK Government should present this information to the oil, gas and coal companies with a polite request for them to unveil their plan of action in the face of this undeniable problem.”

There is no reason why this story should be covered in BBC News by Roger Harrabin. What can anybody reading it do about the problem ? There is no purpose for this article. It is a pointless statement of concern, or rather, a belittling rehearsal of the concern. Unless this article, and the thousands like it, lead to the Government demanding answers on Energy Change from the fossil fuel companies, there is no point in reporting it, or in this case, disparaging it with faint humour.

The only time that ocean acidification should appear in a media piece is to report that the problem has been presented to the architects of increased ocean carbon dioxide, and answers have been requested.

And who are the architects of increased atmospheric and ocean carbon dioxide ? Those who mine fossil fuels. Those companies like BP and Shell, ExxonMobil, and all the coal extraction companies should act. They should offer us alternative non-fossil fuel energy. And the news should be about how these companies are taking action to offer us Renewable Hydrogen, Renewable Methane, solar power, wind power and Zero Carbon transport fuels.

Answers from the past will simply not do. Trying to assert that somebody needs to pay for pollution won’t prevent pollution occurring. Carbon taxes or carbon pricing won’t work – since they won’t prevent the mining of fossil fuels – and if fossil fuels are mined, of course they will be burned. Carbon combustion quotas won’t work – since economic wealth is based on burning carbon, so many forces will conspire to maintain levels of fossil fuel combustion. Carbon mining quotas won’t work, since the forces for increasing mining quotas are strong. Carbon trading won’t work, since it won’t reduce the amount of fossil fuels mined – because, obviously, if fossil fuels are mined, they will be burned.

I am tired of reading about climate change, global warming, freshwater stress and ocean acidification in the news. It seems there is nothing I can do that I have not already done that can provide a solution to these problems. Enough with communicating the disaster. I want to read about engineering and energy companies who have switched business models to producing Zero Carbon energy. I want to hear how energy security concern is taking oil, gas and coal companies towards Renewable Everything.

I will probably fail to make myself understood, yet again, but here goes…

The reasons the United Nations Climate Change process is failing are :-

1. The wrong people are being asked to shoulder responsibility

It is a well-rumoured possibility that the fossil fuel industry makes sure it has sympathisers and lobbyists at the United Nations Framework Convention on Climate Change (UNFCCC) conferences. It is only natural that they should want to monitor proceedings, and influence outcomes. But interventions by the energy sector has a much wider scope. Delegates from the countries with national oil and gas companies are key actors at UNFCCC conferences. Their national interests are closely bound to their fossil fuel exports. Many other countries understand their national interest is bound to the success of energy sector companies operating within their borders. Still others have governments with energy policy virtually dictated by international energy corporations. Yet when the UNFCCC discusses climate change, the only obligations discussed are those of nations – the parties to any treaty are the governments and regimes of the world. The UNFCCC does not hold oil and gas (and coal) companies to account. BP and Shell (and Exxon and Chevron and Total and GDF Suez and Eni and so on) are not asked to make undertakings at the annual climate talks. Governments are hoped to forge a treaty, but this treaty will create no leverage for change; no framework of accountability amongst those who produce oil, gas and coal.

2. The right people are not in the room

It’s all very well for Governments to commit to a treaty, but they cannot implement it. Yes, their citizens can make a certain amount of changes, and reduce their carbon emissions through controlling their energy consumption and their material acquisitions. But that’s not the whole story. Energy has to be decarbonised at source. There are technological solutions to climate change, and they require the deployment of renewable energy systems. The people who can implement renewable energy schemes should be part of the UNFCCC process; the engineering companies who make wind turbines, solar photovoltaic panels, the people who can build Renewable Gas systems. Companies such as Siemens, GE, Alstom. Energy engineering project companies. Chemical engineering companies.

3. The economists are still in the building

In the United Kingdom (what will we call it if Scotland becomes independent ? And what will the word “British” then mean ?) the Parliament passed the Climate Change Act. But this legislation is meaningless without a means to implement the Carbon Budgets it institutes. The British example is just a minor parallel to the UNFCCC situation – how can a global climate treaty be made to work ? Most of the notions the economists have put forward so far to incentivise energy demand reduction and stimulate low carbon energy production have failed to achieve much. Carbon trading ! Carbon pricing ! All rather ineffective. Plus, there’s the residual notion of different treatment for developed and developing nations, which is a road to nowhere.

4. Unilateral action is frowned upon

Apparently, since Climate Change is a global problem, we all have to act in a united fashion to solve it. But that’s too hard to ask, at least to start with. When countries or regions take it upon themselves to act independently, the policy community seem to counsel against it. There are a few exceptions, such as the C40 process, where individual cities are praised for independent action, but as soon as the European Community sets up something that looks like a border tax on carbon, that’s a no-no. Everybody is asked to be part of a global process, but it’s almost too hard to get anything done within this framework.

5. Civil Society is hamstrung and tongue-tied

There is very little that people groups can achieve within the UNFCCC process, because there is a disconnect between the negotiations and practical action. The framework of the treaty discussions does not encompass the real change makers. The UNFCCC does not build the foundation for the architecture of a new green economy, because it only addresses itself to garnering commitments from parties that cannot fulfill them. Civil Society ask for an egg sandwich and they are given a sandy eggshell. If Civil Society groups call for technology, they are given a carbon credit framework. If they call for differential investment strategies that can discredit carbon dependency, they are given an opportunity to put money into the global adaptation fund.

How to organise a political campaign around Climate Change : ask a group of well-fed, well-meaning, Guardian-reading, philanthropic do-gooders into the room to adopt the lowest common denominator action plan. Now, as a well-fed, well-meaning, Guardian-reading (well, sometimes), philanthropic do-gooder myself, I can expect to be invited to attend such meetings on a regular basis. And always, I find myself frustrated by the outcomes : the same insipid (but with well-designed artwork) calls to our publics and networks to support something with an email registration, a signed postcard, a fistful of dollars, a visit to a public meeting of no consequence, or a letter to our democratic representative. No output except maybe some numbers. Numbers to support a government decision, perhaps, or numbers to indicate what kind of messaging people need in future.

I mean, with the Fair Trade campaign, at least there was some kind of real outcome. Trade Justice advocates manned stall tables at churches, local venues, public events, and got money flowing to the international co-operatives, building up the trade, making the projects happen, providing schooling and health and aspirations in the target countries. But compare that to the Make Poverty History campaign which was largely run to support a vain top-level political attempt to garner international funding promises for social, health and economic development. Too big to succeed. No direct line between supporting the campaign and actually supporting the targets. Passing round the hat to developed, industrialised countries for a fund to support change in developing, over-exploited countries just isn’t going to work. Lord Nicholas Stern tried to ask for $100 billion a year by 2020 for Climate Change adaptation. This has skidded to a halt, as far as I know. The economic upheavals, don’t you know ?

And here we are again. The United Nations Framework Convention on Climate Change (UNFCCC), which launched the Intergovernmental Panel on Climate Change (IPCC) reports on climate change, oh, so, long, ago, through the person of its most charismatic and approachable Executive Secretary, Christiana Figueres, is calling for support for a global Climate Change treaty in 2015. Elements of this treaty, being drafted this year, will, no doubt, use the policy memes of the past – passing round the titfer begging for a couple of billion squid for poor, hungry people suffering from floods and droughts; proposing some kind of carbon pricing/taxing/trading scheme to conjure accounting bean solutions; trying to implement an agreement around parts per million by volume of atmospheric carbon dioxide; trying to divide the carbon cake between the rich and the poor.

Somehow, we believe, that being united around this proposed treaty, few of which have any control over the contents of, will bring us progress.

What can any of us do to really have input into the building of a viable future ? Christiana – for she is now known frequently only by her first name – has called for numbers – a measure of support for the United Nations process. She has also let it be known that if there is a substantial number of people who, with their organisations, take their investments out of fossil fuels, then this could contribute to the mood of the moment. Those who are advocating divestment are yet small in number, and I fear that they will continue to be marginal, partly because of the language that is being used.

First of all, there are the Carbon Disclosers. Their approach is to conjure a spectre of the “Carbon Bubble” – making a case that investments in carbon dioxide-rich enterprises could well end up being stranded by their assets, either because of wrong assumptions about viable remaining resources of fossil fuels, or because of wrong assumptions about the inability of governments to institute carbon pricing. Well, obviously, governments will find it hard to implement effective carbon pricing, because governments are in bed with the energy industry. Politically, governments need to keep big industry sweet. No surprise there. And it’s in everybody’s interests if Emperor Oil and Prince Regent Natural Gas are still wearing clothes. In the minds of the energy industry, we still have a good four decades of healthy fossil fuel assets. Royal Dutch Shell’s CEO can therefore confidently say at a public AGM that There Is No Carbon Bubble. The Carbon Discloser language is not working, it seems, as any kind of convincer, except to a small core of the concerned.

And then there are the Carbon Voices. These are the people reached by email campaigns who have no real idea how to do anything practical to affect change on carbon dioxide emissions, but they have been touched by the message of the risks of climate change and they want to be seen to be supporting action, although it’s not clear what action will, or indeed can, be taken. Well-designed brochures printed on stiff recycled paper with non-toxic inks will pour through their doors and Inboxes. Tick it. Send it back. Sign it. Send it on. Maybe even send some cash to support the campaign. This language is not achieving anything except guilt.

And then there are the Carbon Divestors. These are extremely small marginal voices who are taking a firm stand on where their organisations invest their capital. The language is utterly dated. The fossil fuel industry are evil, apparently, and investing in fossil fuels is immoral. It is negative campaigning, and I don’t think it stands a chance of making real change. It will not achieve its goal of being prophetic in nature – bearing witness to the future – because of the non-inclusive language. Carbon Voices reached by Carbon Divestor messages will in the main refuse to respond, I feel.

Political action on Climate Change, and by that I mean real action based on solid decisions, often taken by individuals or small groups, has so far been under-the-radar, under-the-counter, much like the Fair Trade campaign was until it burst forth into the glorious day of social acceptability and supermarket supply chains. You have the cyclists, the Transition Towners, the solar power enthusiasts. Yet to get real, significant, economic-scale transition, you need Energy Change – that is, a total transformation of the energy supply and use systems. It’s all very well for a small group of Methodist churches to pull their pension funds from investments in BP and Shell, but it’s another thing entirely to engage BP and Shell in an action plan to diversify out of petroleum oil and Natural Gas.

Here below are my email words in my feeble attempt to challenge the brain of Britain’s charitable campaigns on what exactly is intended for the rallying cry leading up to Paris 2015. I can pretty much guarantee you won’t like it – but you have to remember – I’m not breaking ranks, I’m trying to get beyond the Climate Change campaigning and lobbying that is currently in play, which I regard as ineffective. I don’t expect a miraculous breakthrough in communication, the least I can do is sow the seed of an alternative. I expect I could be dis-invited from the NGO party, but it doesn’t appear to be a really open forum, merely a token consultation to build up energy for a plan already decided. If so, there are probably more important things I could be doing with my time than wasting hours and hours and so much effort on somebody else’s insipid and vapid agenda.

I expect people might find that attitude upsetting. If so, you know, I still love you all, but you need to do better.

[…]

A lot of campaigning over the last 30 years has been very negative and divisive, and frequently ends in psychological stalemate. Those who are cast as the Bad Guys cannot respond to the campaigning because they cannot admit to their supporters/employees/shareholders that the campaigners are “right”. Joe Average cannot support a negative campaign as there is no apparent way to make change happen by being so oppositional, and because the ask is too difficult, impractical, insupportable. [Or there is simply too much confusion or cognitive dissonance.]

One of the things that was brought back from the […] working group breakout on […] to the plenary feedback session was that there should be some positive things about this campaign on future-appropriate investment. I think […] mentioned the obvious one of saying effectively “we are backing out of these investments in order to invest in things that are more in line with our values” – with the implicit encouragement for fossil fuel companies to demonstrate that they can be in line with our values and that they are moving towards that. There was some discussion that there are no bulk Good Guy investment funds, that people couldn’t move investments in bulk, although some said there are. […] mentioned Ethex.

Clearly fossil fuel production companies are going to find it hard to switch from oil and gas to renewable electricity, so that’s not a doable we can ask them for. Several large fossil fuel companies, such as BP, have tried doing wind and solar power, but they have either shuttered those business units, or not let them replace their fossil fuel activities.

[…] asked if the [divestment] campaign included a call for CCS – Carbon Capture and Storage – and […] referred to […] which showed where CCS is listed in a box on indicators of a “good” fossil fuel energy company.

I questioned whether the fossil fuel companies really want to do CCS – and that they have simply been waiting for government subsidies or demonstration funds to do it. (And anyway, you can’t do CCS on a car.)

I think I said in the meeting that fossil fuel producer companies can save themselves and save the planet by adopting Renewable Gas – so methods for Carbon Capture and Utilisation (CCU) or “carbon recycling”. Plus, they could be making low carbon gas by using biomass inputs. Most of the kit they need is already widely installed at petrorefineries. So – they get to keep producing gas and oil, but it’s renewably and sustainably sourced with low net carbon dioxide emissions. That could be turned into a positive, collaborative ask, I reckon, because we could all invest in that, the fossil fuel companies and their shareholders.

Anyway, I hope you did record something urging a call to positive action and positive engagement, because we need the co-operation of the fossil fuel companies to make appropriate levels of change to the energy system. Either that, or they go out of business and we face social turmoil.

If you don’t understand why this is relevant, that’s OK. If you don’t understand why a straight negative campaign is a turn-off to many people (including those in the fossil fuel industry), well, I could role play that with you. If you don’t understand what I’m talking about when I talk about Renewable Gas, come and talk to me about it again in 5 years, when it should be common knowledge. If you don’t understand why I am encouraging positive collaboration, when negative campaigning is so popular and marketable to your core segments, then I will resort to the definition of insanity – which is to keep doing the same things, expecting a different result.

I’m sick and tired of negative campaigning. Isn’t there a more productive thing to be doing ?

There are no enemies. There are no enemies. There are no enemies.

——-

As far as I understand the situation, both the […] and […] campaigns are negative. They don’t appear to offer any positive routes out of the problem that could engage the fossil fuel companies in taking up the baton of Energy Change. If that is indeed the main focus of […] and […] efforts, then I fear they will fail. Their work will simply be a repeat of the negative campaigning of the last 30 years – a small niche group will take up now-digital placards and deploy righteous, holy social media anger, and that will be all.

Since you understand this problem, then I would suggest you could spend more time and trouble helping them to see a new way. You are, after all, a communications expert. And so you know that even Adolf Hitler used positive, convening, gathering techniques of propaganda to create power – and reserved the negative campaigning for easily-marginalised vulnerable groups to pile the bile and blame on.

Have a nicer day,

—–

The important thing as far as I understand it is that the “campaigning” organisations need to offer well-researched alternatives, instead of just complaining about the way things are. And these well-researched alternatives should not just be the token sops flung at the NGOs and UN by the fossil fuel companies. What do I mean ?

Well, let’s take Carbon Capture and Storage (CCS). The injection of carbon dioxide into old oil and gas caverns was originally proposed for Enhanced Oil Recovery (EOR) – that is – getting more oil and gas out the ground by pumping gas down there – a bit like fracking, but with gas instead of liquid. The idea was that the expense of CCS would be compensated for by the new production of oil and gas – however, the CCS EOR effect has shown to be only temporary. So now the major oil and gas companies say they support carbon pricing (either by taxation or trading), to make CCS move forward. States and federations have given them money to do it. I think the evidence shows that carbon pricing cannot be implemented at a sufficiently high level to incentivise CCS, therefore CCS is a non-answer. Why has […] not investigated this ? CCS is a meme, but not necessarily part of the carbon dioxide solution. Not even the UNFCCC IPCC reports reckon that much CCS can be done before 2040. So, why does CCS appear in the […] criteria for a “good” fossil fuel company ? Because it’s sufficiently weak as a proposal, and sufficiently far enough ahead that the fossil fuel companies can claim they are “capture ready”, and in the Good Book, but in reality are doing nothing.

Non-starters don’t just appear from fossil fuel companies. From my point of view, another example of running at and latching on to things that cannot help was the support of the GDR – Greenhouse Development Rights, of which there has been severe critique in policy circles, but the NGOs just wrote it into their policy proposals without thinking about it. There is no way that the emissions budgets set out in the GDR policy could ever get put into practice. For a start, there is no real economic reason to divide the world into developing and developed nations (Kyoto [Protocol]’s Annex I and Annex II).

If you give me some links, I’m going to look over your […] and think about it.

I think that if a campaign really wants to get anywhere with fossil fuel companies, instead of being shunted into a siding, it needs to know properly what the zero carbon transition pathways really are. Unequal partners do not make for a productive engagement, I reckon.

—–

I’m sorry to say that this still appears to be negative campaigning – fossil fuel companies are “bad”; and we need to pull our money out of fossil fuel companies and put it in other “good” companies. Where’s the collective, co-operative effort undertaken with the fossil fuel companies ? What’s your proposal for helping to support them in evolving ? Do you know how they can technologically transition from using fossil fuels to non-fossil fuels ? And how are you communicating that with them ?

——

They call me the “Paradigm Buster”. I’m not sure if “the group” is open to even just peeking into that kind of approach, let alone “exploring” it. The action points on the corporate agenda could so easily slip back into the methods and styles of the past. Identify a suffering group. Build a theory of justice. Demand reparation. Make Poverty History clearly had its victims and its saviours. Climate change, in my view, requires a far different treatment. Polar bears cannot substitute for starving African children. And not even when climate change makes African children starve, can they inspire the kind of action that climate change demands. A boycott campaign without a genuine alternative will only touch a small demographic. Whatever “the group” agrees to do, I want it to succeed, but by rehashing the campaigning strategies and psychology of the past, I fear it will fail. Even by adopting the most recent thinking on change, such as Common Cause, [it] is not going to surmount the difficulties of trying to base calls to action on the basis of us-and-them thinking – polar thinking – the good guys versus the bad guys – the body politic David versus the fossil fuel company Goliath. By challenging this, I risk alienation, but I am bound to adhere to what I see as the truth. Climate change is not like any other disaster, aid or emergency campaign. You can’t just put your money in the [collecting tin] and pray the problem will go away with the help of the right agencies. Complaining about the “Carbon Bubble” and pulling your savings from fossil fuels is not going to re-orient the oil and gas companies. The routes to effective change require a much more comprehensive structure of actions. And far more engagement that agreeing to be a flag waver for whichever Government policy is on the table. I suppose it’s too much to ask to see some representation from the energy industry in “the group”, or at least […] leaders who still believe in the fossil fuel narratives, to take into account their agenda and their perspective, and a readiness to try positive collaborative change with all the relevant stakeholders ?

It was probably a side-effect of the flu’, but as I was listening to Christiana Figueres speaking at St Paul’s Cathedral, London, this evening, I started to have tunnel vision, and the rest of the “hallowed halls” just melted away, and I felt she was speaking to me individually, woman to woman.

She talked a lot about investments, injustices and inertia, but I felt like she was personally calling me, nagging me, bugging me to show more love. She said she didn’t want us to leave thinking “That was interesting”, or even “That was inspiring”, but that we would leave resolved to do one more concrete thing to show our love for our world, and our fellow human beings.

I was a little defensive inside – I’m already trying to get some big stuff done – how could I do anything else that could be effective ? She said that we couldn’t ask people to do more if we weren’t prepared to do more ourselves. I wasn’t sure that any of the things she suggested I could try would have any impact, but I suppose I could try again to write to my MP Iain Duncan Smith – after all, Private Eye tells me he’s just hired a communications consultant, so he might be willing to communicate with me about climate change, perhaps.

Of her other suggestions, I have already selected investments that are low carbon, so there would be little point in writing to them about carbon-based “stranded assets”. My diet is very largely vegetarian; I buy food and provisions from co-operatives where I can; I don’t own a car; I’ve given up flying; I’ve installed solar electricity; my energy consumption is much lower than average; I buy secondhand; I reuse, repair, reclaim, recycle.

I don’t want to “campaign” on climate change – I don’t think that would be very loving. This should not be a public relations mission, it needs to be authentic and inclusive, so I don’t know what the best way is to engage more people in “the struggle”. I’ve sent enough email in my life. People already know about climate change, I don’t need to evangelise them. They already know some of the things they could do to mitigate their fossil fuel energy consumption, I don’t need to educate them. The organisations that are still pushing fossil fuels to society have more to do to get with the transition than everyday energy consumers, surely ?

So, how is it that this “love bug” bites me ? What do I feel bugged to be getting on with ? Researching low carbon gas energy systems is my main action at the moment, but what could I do that would be an answer to Christiana’s call for me to do something extra ? Join in the monthly fast and prayer that’s due to start on 1st November ? Well, sure I will, as part of my work duties. Network for Our Voices that will funnel the energy of the monthly call to prayer into a Civil Society “tornado” in support of the UNFCCC Paris Treaty ? Yes, of course. Comes with the territory. But more… ?

I noticed that Christiana Figueres had collegiate competition from the bells of St Paul’s, and it sounded like the whole cathedral was ringing. Then my cough started getting bad and I started to feel quite unwell, so I had to leave before the main debate took place, to medicate myself with some fresh orange juice from a company I chose because it tracks its carbon, and has a proper plan for climate sustainability, so I never answered my question – what do I need to do, to do more about climate change ?

I researching the history of the development of the gas industry in the United Kingdom, and some of the parallel evolution of the industry in the United States of America and mainland Europe.

In looking at the period of the mid- to late- 1960s, and the British decision to transition from manufactured gas to Natural Gas supplies, I have been able to answer some of my questions, but not all of them, so far.

From a variety of sources, I have been able to determine that there were contingency plans to provide substitutes for Natural Gas, either to solve technical problems in the grid conversion away from town gas, or to compensate should North Sea Natural Gas production growth be sluggish, or demand growth higher than anticipated.

Technologies included the enriching of “lean” hydrogen-rich synthesis gas (reformed from a range of light hydrocarbons, by-products of the petroleum refining industry); Synthetic Natural Gas (SNG) and methane-“rich” gas making processes; and simple mixtures of light hydrocarbons with air.

In the National Archives Cmd/Cmnd/Command document 3438 “Fuel Policy. Presented to Parliament by the Minister of Power Nov 1967”, I found discussion on how North Sea gas fields could best be exploited, and about expected depletion rates, and that this could promote further exploration and discovery.

In a range of books and papers of the time, I have found some discussion about options to increase imports of Natural Gas, either by the shipping of Liquified Natural Gas (LNG) or by pipeline from The Netherlands.

Current British policy in respect of Natural Gas supplies appears to rest on “pipeline diplomacy”, ensuring imports through continued co-operation with partner supplier countries and international organisations.

I remain unclear about what official technological or structural strategy may exist to bridge the gap between depleting North Sea Natural Gas supplies and continued strong demand, in the event of failure of this policy.

It is clear from my research into early gas field development that depletion is inevitable, and that although some production can be restored with various techniques, that eventually wells become uneconomic, no matter what the size of the original gas field.

To my mind, it seems unthinkable that the depletion of the North Sea gas fields was unanticipated, and yet I have yet to find comprehensive policy statements that cover this eventuality and answer its needs.

Under the Freedom of Information Act (2000), I am requesting information to answer the following questions :-

1. At the time of European exploration for Natural Gas in the period 1948 to 1965, and the British conversion from manufactured gas to Natural Gas, in the period 1966 to 1977, what was HM Government’s policy to compensate for the eventual depletion of the North Sea gas fields ?

2. What negotiations and agreements were made between HM Government and the nationalised gas industry between 1948 and 1986; and between HM Government and the privatised gas industry between 1986 and today regarding the projections of decline in gas production from the UK Continental Shelf, and any compensating strategy, such as the development of unconventional gas resources, such as shale gas ?

3. Is there any policy or strategy to restore the SNG (Synthetic Natural Gas) production capacity of the UK in the event of a longstanding crisis emerging, for example from a sharp rise in imported Natural Gas costs or geopolitical upheaval ?

4. Has HM Government any plan to acquire the Intellectual Property rights to SNG production technology, whether from British Gas/Centrica or any other private enterprise, especially for the slagging version of the Lurgi gasifier technology ?

5. Has HM Government any stated policy intention to launch new research and development into, or pilot demonstrations of, SNG ?

6. Does HM Government have any clearly-defined policy on the production and use of manufactured gas of any type ? If so, please can I know references for the documents ?

7. Does HM Government anticipate that manufactured gas production could need to increase in order to support the production of synthetic liquid vehicle fuels; and if so, which technologies are to be considered ?

An engineering buddy and I find ourselves in my kitchen, reading out loud from Jeremy Leggett’s 2013 book “The Energy of Nations : Risk Blindness and the Road to Renaissance”. The main topic of the work, I feel, is the failure of the energy sector and the political elites to develop a realistic plan for the future, and their blinkered adherence to clever arguments taken from failing and cracked narratives – such as the belief that unconventional fossil fuels, such as tar sands, can make up for declining conventional oil and gas production. It’s also about compromise of the highest order in the most influential ranks. The vignettes recalling conversations with the high and mighty are pure comedy.

“It’s very dramatic…”

“You can imagine it being taken to the West End theatres…”

“We should ask Ben Elton to take a look – adapt it for the stage…”

“It should really have costumes. Period costumes…Racy costumes…”

“Vaudeville ?”

“No…burlesque ! Imagine the ex-CEO of BP, John Browne, in a frou-frou tutu, slipping a lacy silk strap from his shoulder…What a Lord !”

In the last few weeks I have heard a lot of noble but futile hopes on the subject of carbon dioxide emissions control.

People always seem to want to project too far into the future and lay out their wonder solution – something that is just too advanced enough to be attainable through any of the means we currently have at our disposal. It is impossible to imagine how the gulf can be bridged between the configuration of things today and their chosen future solutions.

Naive civil servants strongly believe in a massive programme of new nuclear power. Head-in-the-clouds climate change consultants and engineers who should know otherwise believe in widespread Carbon Capture and Storage or CCS. MBA students believe in carbon pricing, with carbon trading, or a flat carbon tax. Social engineers believe in significant reductions in energy intensity and energy consumer behaviour change, and economists believe in huge cost reductions for all forms of renewable electricity generation.

To make any progress at all, we need to start where we are. Our economic system has strong emissions-dependent components that can easily be projected to fight off contenders. The thing is, you can’t take a whole layer of bricks out of a Jenga stack without severe degradation of its stability. You need to work with the stack as it is, with all the balances and stresses that already exist. It is too hard to attempt to change everything at once, and the glowing ethereal light of the future is just too ghostly to snatch a hold of without a firm grasp on an appropriate practical rather than spiritual guide.

Here’s part of an email exchange in which I strive for pragmatism in the face of what I perceive as a lack of realism.

To: Jo

I read your article with interest. You have focused on energy, whereas I
tend to focus on total resource. CCS does make sense and should be pushed
forward with real drive as existing power stations can be cleaned up with it
and enjoy a much longer life. Establishing CCS is cheaper than building new
nuclear and uses far less resources. Furthermore, CCS should be used on new
gas and biomass plants in the future.

What we are lacking at the moment is any politician with vision in this
space. Through a combination of boiler upgrades, insulation, appliance
upgrades and behaviour change, it is straight forward to halve domestic
energy use. Businesses are starting to make real headway with energy
savings. We can therefore maintain a current total energy demand for the
foreseeable future.

To service this demand, we should continue to eke out every last effective
joule from the current generating stock by adding cleansing kit to the dirty
performers. While this is being done, we can continue to develop renewable
energy and localised systems which can help to reduce the base load
requirement even further.

From an operational perspective, CCS has stagnated over the last 8 years, so
a test plant needs to be put in place as soon as possible.

The biggest issue for me is that, through political meddling and the
unintended consequences of ill-thought out subsidies, the market has been
skewed in such a way that the probability of a black-out next year is very
high indeed.

Green gas is invisible in many people’s thinking, but the latest House of
Lords Report highlighted its potential.

Vested interests are winning hands down in the stand-off with the big
picture!

From: Jo

What is the title of the House of Lords report to which you refer ?

Sadly, I am old enough to remember Carbon Capture and Storage (CCS)
the first time the notion went around the block, so I’d say that
progress has been thin for 30 years rather than 8.

Original proposals for CCS included sequestration at the bottom of the
ocean, which have only recently been ruled out as the study of global
ocean circulation has discovered more complex looping of deep and
shallower waters that originally modelled – the carbon dioxide would
come back up to the surface waters eventually…

The only way, I believe, that CCS can be made to work is by creating a
value stream from the actual carbon dioxide, and I don’t mean Enhanced
Oil Recovery (EOR).

And I also definitely do not mean carbon dioxide emissions pricing,
taxation or credit trading. The forces against an
investment-influencing carbon price are strong, if you analyse the
games going on in the various economic system components. I do not
believe that a strong carbon price can be asserted when major economic
components are locked into carbon – such as the major energy producers
and suppliers, and some parts of industry, and transport.

Also, carbon pricing is designed to be cost-efficient, as markets will
always find the lowest marginal pricing for any externality in fines
or charges – which is essentially what carbon dioxide emissions are.
The EU Emissions Trading Scheme was bound to deliver a low carbon
price – that’s exactly what the economists predicted in modelling
carbon pricing.

I cannot see that a carbon price could be imposed that was more than
5% of the base commodity trade price. At those levels, the carbon
price is just an irritation to pass on to end consumers.

The main problem is that charging for emissions does not alter
investment decisions. Just like fines for pollution do not change the
risks for future pollution. I think that we should stop believing in
negative charging and start backing positive investment in the energy
transition.

You write “You have focused on energy, whereas I tend to focus on
total resource.” I assume you mean the infrastructure and trading
systems. My understanding leads me to expect that in the current
continuing economic stress, solutions to the energy crisis will indeed
need to re-use existing plant and infrastructure, which is why I
think that Renewable Gas is a viable option for decarbonising total
energy supply – it slots right in to substitute for Natural Gas.

My way to “eke out every last effective joule from the current
generating stock” is to clean up the fuel, rather than battle
thermodynamics and capture the carbon dioxide that comes out the back
end. Although I also recommend carbon recycling to reduce the need for
input feedstock.

I completely agree that energy efficiency – cutting energy demand
through insulation and so on – is essential. But there needs to be a
fundamental change in the way that profits are made in the energy
sector before this will happen in a significant way. Currently it
remains in the best interests of energy production and supply
companies to produce and supply as much energy as they can, as they
have a duty to their shareholders to return a profit through high
sales of their primary products.

“Vested interests” have every right under legally-binding trade
agreements to maximise their profits through the highest possible
sales in a market that is virtually a monopoly. I don’t think this can
be challenged, not even by climate change science. I think the way
forward is to change the commodities upon which the energy sector
thrives. If products from the energy sector include insulation and
other kinds of efficiency, and if the energy sector companies can
continue to make sales of these products, then they can reasonably be
expected to sell less energy. I’m suggesting that energy reduction
services need to have a lease component.

Although Alistair Buchanan formerly of Ofgem is right about the
electricity generation margins slipping really low in the next few
winters, there are STOR contracts that National Grid have been working
on, which should keep the lights on, unless Russia turn off the gas
taps, which is something nobody can do anything much about – not BP,
nor our diplomatic corps, the GECF (the gas OPEC), nor the WTO.

I was looking back over older emails and saw that I had never responded to your note. It arrived as I was headed to MIT to teach for a week and then it got lost. Sorry about that.

Some interesting questions. I don’t know anybody working specifically on wind power to gas options. At one time Shell had a project in Iceland using geothermal to make hydrogen. Don’t know what its status is but if you search on hydrogen and Iceland on the Shell website I’m sure there’s something. If the Germans have power to gas as a real policy option I’d poke around the web for information on who their research partners are for this.

Here are a couple of high level thoughts. Not to discourage you because real progress comes from asking new questions, but there are some physical fundamentals that are important.

Direct air capture of anything using current technology is prohibitively expensive to do at scale for energy. More energy will be expended in capture and synthesis than the fuels would yield.

Gaseous fuels are problematic on their own. Gas doesn’t travel well and is difficult to contain at high energy densities as that means compressing or liquefying it. That doesn’t make anything impossible, but it raises many questions about infrastructure and energy balance. If we take the energy content of a barrel of oil as 1.0, then a barrel of liquefied natural gas is about 0.6, compressed natural gas which is typically at about 3600psi is around 0.3, and a barrel (as a measure of volume equal to 42 US gallons) of natural gas at room temperature and pressure is about 0.0015 (+/-). Also there’s a real challenge in storing and transporting gasses as fuel at scale, particularly motor fuel to replace gasoline and diesel.

While there is some spare wind power potential that doesn’t get utilized because of how the grid must be managed, I expect it is a modest amount of energy compared to what we use today in liquid fuels. I think what that means is that while possible, it’s more likely to happen in niche local markets and applications rather than at national or global scales.

If you haven’t seen it, a nice reference on the potential of various forms of sustainable energy is available free and online here. http://www.withouthotair.com/

Many thanks for getting back to me. Responses are nice – even if they
are months late. As they say – better late than never, although with
climate change, late action will definitely be unwise, according to an
increasing number of people.

I have indeed seen the website, and bought and spilled coffee on the
book of Professor David MacKay’s “Sustainable Energy Without The Hot
Air” project. It is legendary. However, I have checked and he has only
covered alternative gas in a couple of paragraphs – in notes. By
contrast, he spent a long chapter discussing how to filter uranium out
of seawater and other nuclear pursuits.

Yet as a colleague of mine, who knows David better than I do, said to
me this morning, his fascination with nuclear power is rather naive,
and his belief in the success of Generation III and Generation IV
lacks evidence. Plus, if we get several large carbon dioxide
sequestration projects working in the UK – Carbon Capture and Storage
(CCS) – such as the Drax pipeline (which other companies will also
join) and the Shell Peterhead demonstration, announced today, then we
won’t need new nuclear power to meet our 4th Carbon Budget – and maybe
not even the 5th, either (to be negotiated in 2016, I hear) :-

We don’t need to bury this carbon, however; we just need to recycle
it. And the number of ways to make Renewable Hydrogen, and
energy-efficiently methanate carbon monoxide and carbon dioxide with
hydrogen, is increasing. People are already making calculations on how
much “curtailed” or spare wind power is likely to be available for
making gas in 10 years’ time, and if solar power in the UK is
cranked/ramped up, then there will be lots of juicy cost-free power
ours for the taking – especially during summer nights.

Direct Air Capture of carbon dioxide is a nonsensical proposition.
Besides being wrong in terms of the arrow of entropy, it also has the
knock-on effect of causing carbon dioxide to come back out of the
ocean to re-equilibrate. I recently read a paper by climate scientists
that estimated that whatever carbon dioxide you take out of the air,
you will need to do almost all of it again.

Instead of uranium, we should be harvesting carbon dioxide from the
oceans, and using it to make gaseous and liquid fuels.

Gaseous fuels and electricity complement each other very well –
particularly in storage and grid balancing terms – there are many
provisions for the twins of gas and power in standards, laws, policies
and elsewhere. Regardless of the limitations of gas, there is a huge
infrastructure already in place that can store, pipe and use it, plus
it is multi-functional – you can make power, heat, other fuels and
chemicals from gas. In addition, you can make gas from a range of
resources and feedstocks and processing streams – the key quartet of
chemical gas species keep turning up : hydrogen, methane, carbon
monoxide and carbon dioxide – whether you are looking at the exhaust
from combustion, Natural Gas, industrial furnace producer gas,
biological decomposition, just about everywhere – the same four gases.

Energy transition must include large amounts of renewable electricity
– because wind and solar power are quick to build yet long nuclear
power lead times might get extended in poor economic conditions. The
sun does not always shine and the wind does not always blow (and the
tide is not always in high flux). Since demand profiles will never be
able to match supply profiles exactly, there will always be spare
power capacity that grids cannot use. So Power to Gas becomes the
optimal solution. At least until there are ways to produce Renewable
Hydrogen at plants that use process heat from other parts of the
Renewable Gas toolkit. So the aims are to recycle carbon dioxide from
gas combustion to make more gas, and recycle gas production process
heat to make hydrogen to use in the gas production process, and make
the whole lot as thermally balanced as possible. Yes. We can do that.
Lower the inputs of fresh carbon of any form, and lower the energy
requirements to make manufactured gas.

I met somebody working with Jacobs who was involved in the Carbon
Recycling project in Iceland. Intriguing, but an order of magnitude
smaller than I think is possible.

ITM Power in the UK are doing a Hydrogen-to-gas-grid and methanation
project in Germany with one of the regions. They have done several
projects with Kiwa and Shell on gas options in Europe. I know of the
existence of feasibility reports on the production of synthetic
methane, but I have not had the opportunity to read them yet…

I feel quite encouraged that Renewable Gas is already happening. It’s
a bit patchy, but it’s inevitable, because the narrative of
unconventional fossil fuels has many flaws. I have been looking at
issues with reserves growth and unconventionals are not really
commensurate with conventional resources. There may be a lot of shale
gas in the ground, but getting it out could be a long process, so
production volumes might never be very good. In the USA you’ve had
lots of shale gas – but that’s only been supported by massive drilling
programmes – is this sustainable ?

BP have just finished building lots of dollars of kit at Whiting to
process sour Natural Gas. If they had installed Renewable Gas kit
instead of the usual acid gas and sulfur processing, they could have
been preparing for the future. As I understand it, it is possible to
methanate carbon dioxide without first removing it from the rest of
the gas it comes in – so methanating sour gas to uprate it is a viable
option as far as I can see. The hydrogen sulfide would still need to
be washed out, but the carbon dioxide needn’t be wasted – it can be
made part of the fuel. And when the sour gas eventually thins out,
those now methanating sour gas can instead start manufacturing gas
from low carbon emissions feedstocks and recycled carbon.

A normal, everyday Monday morning at Energy Geek Central. Yes, this is a normal conversation for me to take part in on a Monday morning. Energy geekery at breakfast. Perfect.

Nuclear Flower Power

This whole UK Government nuclear power programme plan is ridiculous ! 75 gigawatts (GW) of Generation III nuclear fission reactors ? What are they thinking ? Britain would need to rapidly ramp up its construction capabilities, and that’s not going to happen, even with the help of the Chinese. (And the Americans are not going to take too kindly to the idea of China getting strongly involved with British energy). And then, we’d need to secure almost a quarter of the world’s remaining reserves of uranium, which hasn’t actually been dug up yet. And to cap it all, we’d need to have 10 more geological disposal repositories for the resulting radioactive spent fuel, and we haven’t even managed to negotiate one yet. That is, unless we can burn a good part of that spent fuel in Generation IV nuclear fission reactors – which haven’t even been properly demonstrated yet ! Talk about unconscionable risk !

Baseload Should Be History By Now, But…

Whatever the technological capability for nuclear power plants to “load follow” and reduce their output in response to a chance in electricity demand, Generation III reactors would not be run as anything except “baseload” – constantly on, and constantly producing a constant amount of power – although they might turn them off in summer for maintenance. You see, the cost of a Generation III reactor and generation kit is in the initial build – so their investors are not going to permit them to run them at low load factors – even if they could.

There are risks to running a nuclear power plant at partial load – mostly to do with potential damage to the actual electricity generation equipment. But what are the technology risks that Hinkley Point C gets built, and all that capital is committed, and then it only runs for a couple of years until all that high burn up fuel crumbles and the reactors start leaking plutonium and they have to shut it down permanently ? Who can guarantee it’s a sound bet ?

If they actually work, running Generation III reactors at constant output as “baseload” will also completely mess with the power market. In all of the scenarios, high nuclear, high non-nuclear, or high fossil fuels with Carbon Capture and Storage (CCS), there will always need to be some renewables in the mix. In all probability this will be rapidly deployed, highly technologically advanced solar power photovoltaics (PV). The amount of solar power that will be generated will be high in summer, but since you have a significant change in energy demand between summer and winter, you’re going to have a massive excess of electricity generation in summer if you add nuclear baseload to solar. Relative to the demand for energy, you’re going to get more Renewable Energy excess in summer and under-supply in winter (even though you get more offshore wind in winter), so it’s critical how you mix those two into your scenario.

The UK Government’s maximum 75 GW nuclear scenario comprises 55 GW Generation III and 20 GW Generation IV. They could have said 40 GW Gen III to feed Gen IV – the spent fuel from Gen III is needed to kick off Gen IV. Although, if LFTR took off, if they had enough fluoride materials there could be a Thorium way into Gen IV… but this is all so technical, no MP [ Member of Parliament ] is going to get their head round this before 2050.

The UK Government are saying that 16 GW of nuclear by 2030 should be seen as a first tranche, and that it could double or triple by 2040 – that’s one heck of a deployment rate ! If they think they can get 16 GW by 2030 – then triple that by 10 years later ? It’s not going to happen. And even 30 GW would be horrific. But it’s probably more plausible – if they can get 16 GW by 2030, they can arguably get double that by 2040.

As a rule of thumb, you would need around 10 tonnes of fissionable fuel to kickstart a Gen IV reactor. They’ve got 106 tonnes of Plutonium, plus 3 or 4 tonnes they recently acquired – from France or Germany (I forget which). So they could start 11 GW of Gen IV – possibly the PRISM – the Hitachi thing – sodium-cooled. They’ve been trying them since the Year Dot – these Fast Reactors – the Breeders – Dounreay. People are expressing more confidence in them now – “Pandora’s Promise” hangs around the narrative that the Clinton administration stopped research into Fast Reactors – Oak Ridge couldn’t be commercial. Throwing sodium around a core 80 times hotter than current core heats – you can’t throw water at it easily. You need something that can carry more heat out. It’s a high technological risk. But then get some French notable nuclear person saying Gen IV technologies – “they’re on the way and they can be done”.

Radioactive Waste Disposal Woes

The point being is – if you’re commissioning 30 GW of Gen III in the belief that Gen IV will be developed – then you are setting yourself up to be a hostage to technological fortune. That is a real ethical consideration. Because if you can’t burn the waste fuel from Gen III, you’re left with up to 10 radioactive waste repositories required when you can’t even get one at the moment. The default position is that radioactive spent nuclear fuel will be left at the power stations where they’re created. Typically, nuclear power plants are built on the coast as they need a lot of cooling water. If you are going for 30 GW you will need a load of new sites – possibly somewhere round the South East of England. This is where climate change comes in – rising sea levels, increased storm surge, dissolving, sinking, washed-away beaches, more extreme storms […] The default spent fuel scenario with numerous coastal decommissioned sites with radioactive interim stores which contain nearly half the current legacy radioactive waste […]

Based on the figures from the new Greenpeace report, I calculate that the added radioactive waste and radioactive spent fuel arisings from a programme of 16 GW of nuclear new build would be 244 million Terabequerel (TBq), compared to the legacy level of 87 million TBq.

The Nuclear Decommissioning Authority (NDA) are due to publish their Radioactive Waste Inventory and their Report on Radioactive Materials not in the Waste Inventory at the end of January 2014. We need to keep a watch out for that, because they may have adapted their anticipated Minimum and Maxmium Derived Inventory.

Politics Is Living In The Past

What you hear from politicians is they’re still talking about “baseload”, as if they’ve just found the Holy Grail of Energy Policy. And failed nuclear power. Then tidal. And barrages. This is all in the past. Stuff they’ve either read – in an article in a magazine at the dentist’s surgery waiting room, and they think, alright I’ll use that in a TV programme I’ve been invited to speak on, like Question Time. I think that perhaps, to change the direction of the argument, we might need to rubbish their contribution. A technological society needs to be talking about gasification, catalysis. If you regard yourselves as educated, and have a technological society – your way of living in the future is not only in manufacturing but also ideas – you need to be talking about this not that : low carbon gas fuels, not nuclear power. Ministers and senior civil servants probably suffer from poor briefing – or no briefing. They are relying on what is literally hearsay – informal discussions, or journalists effectively representing industrial interests. Newspapers are full of rubbish and it circulates, like gyres in the oceans. Just circulates around and around – full of rubbish.

I think part of the problem is that the politicians and chief civil servants and ministers are briefed by the “Old Guard” – very often the ex-nuclear power industry guard. They still believe in big construction projects, with long lead times and massive capital investment, whereas Renewable Electricity is racing ahead, piecemeal, and private investors are desperate to get their money into wind power and solar power because the returns are almost immediate and risk-free.

Together in Electric Dreams

Question : Why are the UK Government ploughing on with plans for so much nuclear power ?

1. They believe that a lot of transport and heat can be made to go electric.
2. They think they can use spent nuclear fuel in new reactors.
3. They think it will be cheaper than everything else.
4. They say it’s vital for UK Energy Security – for emissions reductions, for cost, and for baseload. The big three – always the stated aim of energy policy, and they think nuclear ticks all those three boxes. But it doesn’t.

What they’ll say is, yes, you have to import uranium, but you’ve got a 4 year stock. Any war you’re going to get yourselves involved in you can probably resolve in 4 days, or 4 weeks. If you go for a very high nuclear scenario, you would be taking quite a big share of the global resource of uranium. There’s 2,600 TWh of nuclear being produced globally. And global final energy demand is around 100,000 TWh – so nuclear power currently produces around 2.6% of global energy supply. At current rates of nuclear generation, according to the World Nuclear Association, you’ve got around 80 years of proven reserves and probably a bit more. Let’s say you double nuclear output by 2050 or 2040 – but in the same time you might just have enough uranium – and then find a bit more. But global energy demand rises significantly as well – so nuclear will still only provide around 3% of global energy demand. That’s not a climate solution – it’s just an energy distraction. All this guff about fusion. Well.

Cornering The Market In Undug Uranium

A 75 GW programme would produce at baseload 590 TWh a year – divide by 2,600 – is about 23% of proven global uranium reserves. You’re having to import, regardless of what other countries are doing, you’re trying to corner the market – roughly a quarter. Not even a quarter of the market – a quarter of all known reserves – it’s not all been produced yet. It’s still in the ground. So could you be sure that you could actually run these power stations if you build them ? Without global domination of the New British Empire […]. The security issues alone – defending coastal targets from a tweeb with a desire to blow them up. 50 years down the line they’re full of radioactive spent fuel that won’t have a repository to go to – we don’t want one here – and how much is it going to cost ?

My view is that offshore wind will be a major contributor in a high or 100% Renewable Electricity scenario by 2050 or 2060. Maybe 180 GW, that will also be around 600 TWh a year – comparable to that maximum nuclear programme. DECC’s final energy demand 2050 – several scenarios – final energy demand from 6 scenarios came out as between roughly 1,500 TWh a year and the maximum 2,500 TWh. Broadly speaking, if you’re trying to do that just with Renewable Electricity, you begin to struggle quite honestly, unless you’re doing over 600 TWh of offshore wind, and even then you need a fair amount of heat pump stuff which I’m not sure will come through. The good news is that solar might – because of the cost and technology breakthroughs. That brings with it a problem – because you’re delivering a lot of that energy in summer. The other point – David MacKay would say – in his book his estimate was 150 TWh from solar by 2050, on the grounds that that’s where you south-facing roofs are – you need to use higher efficiency triple junction cells with more than 40% efficiency and this would be too expensive for a rollout which would double or triple that 150 TWh – that would be too costly – because those cells are too costly. But with this new stuff, you might get that. Not only the cost goes down, but the coverage goes down. Not doing solar across swathes of countryside. There have always been two issues with solar power – cost and where it’s being deployed.

Uh-Oh, Summer Days. Uh-Oh, Summer Nights

With the solar-wind headline, summer days and summer nights are an issue.

With the nuclear headline, 2040 – they would have up to 50 GW, and that would need to run at somewhere between 75% and 95% capacity – to protect the investment and electric generation turbines.

It will be interesting to provide some figures – this is how much over-capacity you’re likely to get with this amount of offshore wind. But if you have this amount of nuclear power, you’ll get this amount […]

Energy demand is strongly variable with season. We have to consider not just power, but heat – you need to get that energy out in winter – up to 4 times as much during peak in winter evenings. How are you going to do that ? You need gas – or you need extensive Combined Heat and Power (CHP) (which needs gas). Or you need an unimaginable deployment of domestic heat pumps. Air source heat pumps won’t work at the time you need them most. Ground source heat pumps would require the digging up of Britain – and you can’t do that in most urban settings.

District Heat Fields

The other way to get heat out to everyone in a low carbon world – apart from low carbon gas – is having a field-based ground source heat pump scheme – just dig up a field next to a city – and just put in pipes and boreholes in a field. You’re not disturbing anybody. You could even grow crops on it next season. Low cost and large scale – but would need a District Heating (DH) network. There are one or two heat pump schemes around the world. Not sure if they are used for cooling in summer or heat extraction in the winter. The other thing is hot water underground. Put in an extra pipe in the normal channels to domestic dwellings. Any excess heat from power generation or electrolysis or whatever is put down this loop and heats the sub-ground. Because heat travels about 1 metre a month in soil, that heat should be retained for winter. A ground source heat sink. Geothermal energy could come through – they’re doing a scheme in Manchester. If there’s a nearby heat district network – it makes it easier. Just want to tee it into the nearest DH system. The urban heat demand is 150 TWh a year. You might be able to put DH out to suburban areas as well. There are 9 million gas-connected suburban homes – another about 150 TWh there as well – or a bit more maybe. Might get to dispose of 300 TWh in heat through DH. The Green Deal insulation gains might not be what is claimed – and condensing gas boiler efficiencies are not that great – which feeds into the argument that in terms of energy efficiency, you not only want to do insulation, but also DH – or low carbon gas. Which is the most cost-effective ? Could argue reasonable energy efficiency measures are cheapest – but DH might be a better bet. That involves a lot of digging.

Gas Is The Logical Answer

But everything’s already laid for gas. (…but from the greatest efficiency first perspective, if you’re not doing DH, you’re not using a lot of Renewable Heat you could otherwise use […] )

The best package would be the use of low carbon gases and sufficient DH to use Renewable Heat where it is available – such as desalination, electrolysis or other energy plant. It depends where the electrolysis is being done.

The Age of Your Carbon

It also depends on which carbon atoms you’re using. If you are recycling carbon from the combustion of fossil fuels into Renewable Gas, that’s OK. But you can’t easily recapture carbon emissions from the built environment (although you could effectively do that with heat storage). You can’t do carbon capture from transport either. So your low carbon gas has to come from biogenic molecules. Your Renewable Gas has to be synthesised using biogenic carbon molecules rather than fossil ones.

[…] I’m using the phrase “Young Carbon”. Young Carbon doesn’t have to be from plants – biological things that grow.

Well, there’s Direct Air Capture (DAC). It’s simple. David Sevier, London-based, is working on this. He’s using heat to capture carbon dioxide. You could do it from exhaust in a chimney or a gasification process – or force a load of air through a space. He would use heat and cooling to create an updraft. It would enable the “beyond capture” problem to be circumvented. Cost is non-competitive. Can be done technically. Using reject heat from power stations for the energy to do it. People don’t realise you can use a lot of heat to capture carbon, not electricity.

Young Carbon from Seawater

If you’re playing around with large amounts of seawater anyway – that is, for desalination for irrigation, why not also do Renewable Hydrogen, and pluck the Carbon Dioxide out of there too to react with the Renewable Hydrogen to make Renewable Methane ? I’m talking about very large amounts of seawater. Not “Seawater Greenhouses” – condensation designs mainly for growing exotic food. If you want large amounts of desalinated water – and you’re using Concentrated Solar Power – for irrigating deserts – you would want to grow things like cacti for biological carbon.

Say you had 40 GW of wind power on Dogger Bank, spinning at 40% load factor a year. You’ve also got electrolysers there. Any time you’re not powering the grid, you’re making gas – so capturing carbon dioxide from seawater, splitting water for hydrogen, making methane gas. Wouldn’t you want to use flash desalination first to get cleaner water for electrolysis ? Straight seawater electrolysis is also being done.

It depends on the relative quantities of gas concentrated in the seawater. If you’ve got oxygen, hydrogen and carbon dioxide, that would be nice. You might get loads of oxygen and hydrogen, and only poor quantities of carbon dioxide ?

But if you could get hydrogen production going from spare wind power. And even if you had to pipe the carbon dioxide from conventional thermal power plants, you’re starting to look at a sea-based solution for gas production. Using seawater, though, chlorine is the problem […]

Look at the relative density of molecules – that sort of calculation that will show if this is going to fly. Carbon dioxide is a very fixed, stable molecule – it’s at about the bottom of the energy potential well – you have to get that reaction energy from somewhere.

How Much Spare Power Will There Be ?

If you’ve got an offshore wind and solar system. At night, obviously, the solar’s not working (unless new cells are built that can run on infrared night-time Earthshine). But you could still have 100 GWh of wind power at night not used for the power grid. The anticipated new nuclear 40 GW nuclear by 2030 will produce about 140 GWh – this would just complicate problems – adding baseload nuclear to a renewables-inclusive scenario. 40 GW is arguably a reasonable deployment of wind power by 2030 – low if anything.

You get less wind in a nuclear-inclusive scenario, but the upshot is you’ve definitely got a lot of power to deal with on a summer night with nuclear power. You do have with Renewable Electricity as well, but it varies more. Whichever route we take we’re likely to end up with excess electricity generation on summer nights.

In a 70 GW wind power deployment (50 GW offshore, 20 GW onshore – 160 TWh a year), you might have something like 50 to 100 GWh per night of excess (might get up to 150 GWh to store on a windy night). But if you have a 16 GW nuclear deployment by 2030 (125 TWh a year), you are definitely going to have 140 GWh of excess per night (that’s 16 GW for 10 hours less a bit). Night time by the way is roughly between 9pm and 7am between peak demands.

We could be making a lot of Renewable Gas !

Can you build enough Renewable Gas or whatever to soak up this excess nuclear or wind power ?

The energy mix is likely to be in reality somewhere in between these two extremes of high nuclear or high wind.

But if you develop a lot of solar – so that it knocks out nuclear power – it will be the summer day excess that’s most significant. And that’s what Germany is experiencing now.

Choices, choices, choices

There is a big choice in fossil fuels which isn’t really talked about very often – whether the oil and gas industry should go for unconventional fossil fuels, or attempt to make use of the remaining conventional resources that have a lower quality. The unconventionals narrative – shale gas, coalbed methane, methane hydrates, deepwater gas, Arctic oil and gas, heavy oil, is running out of steam as it becomes clear that some of these choices are expensive, and environmentally damaging (besides their climate change impact). So the option will be making use of gas with high acid gas composition. And the technological solutions for this will be the same as needed to start major production of Renewable Gas.

Capacity Payments

But you still need to answer the balancing question. If you have a high nuclear power scenario, you need maybe 50 TWh a year of gas-fired power generation. If high Renewable Electricity, you will need something like 100 TWh of gas, so you need Carbon Capture and Storage – or low carbon gas.

Even then, the gas power plants could be running only 30% of the year, and so you will need capacity payments to make sure new flexible plants get built and stay available for use.

If you have a high nuclear scenario, coupled with gas, you can meet the carbon budget – but it will squeeze out Renewable Electricity. If high in renewables, you need Carbon Capture and Storage (CCS) or Carbon Capture and Recycling into Renewable Gas, but this would rule out nuclear power. It depends which sector joins up with which.

Carbon Capture, Carbon Budget

Can the Drax power plant – with maybe one pipeline 24 inches in diameter, carrying away 20 megatonnes of carbon dioxide per year – can it meet the UK’s Carbon Budget target ?

It constantly amazes and intrigues me how human individuals operate in networks to formulate, clarify and standardise ideas, tools, machines, procedures and systems. Several decades ago, Renewable Electricity from sources such as wind power was considered idealistic vapourware, esoteric, unworkable and uncertain, and now it’s a mainstream generator of reliable electricity in the UK’s National Grid. Who would have thought that invisible, odourless, tasteless gas phase chemicals would heat our homes ? It’s now just so normal, it’s impossible to imagine that Natural Gas was once considered to be so insignificant that it was vented – not even flared – from oil wells.

Judging by the sheer number of people working on aspects of Renewable Gas, I expect this too to be mainstream in the energy sector within a decade. What do others think ? I have begun the process of asking, for example, see below.

Yes, I am interested in the idea of “printing” solar cells, which is what I think you might be alluding to with your reference to abalone shells.

But I am more interested in what you base your estimate of “Peak Gas” on. I recently did some very basic modelling of hydrocarbon resources and electricity, which look somewhat different from the IEA and EIA work and reports from BP and Royal Dutch Shell. My conclusion was that Peak Oil is roughly now, Peak Natural Gas will be around 2030, and Peak Electricity around 2060 :-

I am going to try to improve these charts before I submit my MSc Masters Thesis, so I am trying to find out what other people base their projections on. Could you help me by pointing me at the basis of your assessment of Peak Natural Gas ?

I am just now finding a number of old emails that got archived (and ignored) when I moved from MIT to Stanford a few years ago. A quick answer is that I did about what Hubbert did in 1956. No detailed statistical modeling, just look at the trends, think about what’s happening in the industry, and make what seem like reasonable statements about it.

A number of interesting things have happened just in the last two years since you wrote to me. Significantly, US oil production is on the rise. When you count all hydrocarbon liquids, the US is or will soon be, the world largest producer. This just goes to one of my points from TED. Don’t expect oil and gas to go away any time soon. There are plenty of molecules out there. I first said this internally at Shell in the mid 1980’s when I was Manager of Exploration Economics and since then I’ve felt that I got it about right.

I did just look at your website and would caution you about extrapolating very recent trends into the future. The rate of growth in shale gas production has slowed, but there’s an important economic factor driving that. Gas prices in the US are very low compared to oil. With the development of fraccing technology to enable oil and liquids production from shale formations, the industry has shifted their effort to the liquids-rich plays. A few statistics. Gas is currently around $3.50/mcf. On an energy equivalent basis, this equates to an oil price of about $20/barrel. Brent currently sells for $110/barrel and the light oils produced from the shale plays in the US are getting between $90 and $100/barrel, depending on where they can be delivered. As a consequence, in the 3rd quarter of 2013, compared to one year ago, oil well completions are up 18% while natural gas well completions declined 30%.

Yes, you are right. Printing solar cells is an example of what I was talking about with Abalone shells. Similarly, what if you had paint that as it dried would self assemble into linked solar cells and your entire house is now generating electricity. I was totally amazed at the number of people that didn’t actually think about what I was saying and called me an !d!*t for imagining that I was going to transform coal itself into some magical new molecule. […]

In any case, I think it’s good that you’re thinking about these problems, and importantly it appears from your website that you’re thinking about the system and its complexity.

I have personally avoided blogging because I don’t want to put up with people writing mean comments about me. But the data is worth sharing. You should also know the sources of that data otherwise you open yourself to more criticism.

The data on production comes from the International Energy Agency and a research firm PIRA. All of it was in recent press releases. The Energy Information Administration makes similar projections about future production. The data on well completions was recently released by API.

No need to reference me. The data is out there for all to see. But if you do, fair warning. You will get stupid comments about how I used to be a VP at Shell so of course these are the things I’m going to say. […]

By the way, there’s something else that’s very interesting in the world of peak oil and various peaks. I have long believed, as hinted in my TED talk that the most important aspect of peak oil is the demand driven phenomena, not the supply side. It’s worth noting in this context that US oil consumption peaked in 2005 and has declined about 10% since then. This data can be found easily in the BP Statistical Report on World Energy. This is real and is a result of economic shifts, greater efficiency, and the penetration of renewables. Future energy projections (references above) show that this trend continues. A big component of US energy consumption is gasoline, and US gasoline consumption peaked in 2007. I think that data can be found at http://www.eia.gov, although I haven’t looked for it lately. It’s a little factoid that I think I remember.

This year I am hoping to attempt the climb on my own personal K2 by writing an academic book on Renewable Gas – sustainable, low-to-zero carbon emissions gas phase fuels.

I am not a chemist, nor a chemical engineer, and so I would value any suggestions on who I should approach in the gas (and oil) industry to interview about projects that lean in this direction.

Examples would be :-

* Power-to-Gas : Using “spare” wind power to make Renewable Hydrogen – for example by electrolysis of water. Part of the German Power-to-Gas policy. Some hydrogen can be added to gas grids safely without changing regulations, pipework or end appliances.

* Methanation : Using Renewable Hydrogen and young or recycled carbon gas to make methane (using the energy from “spare” wind power, for example). Also part of the German Power-to-Gas policy.

NB “Young” carbon would be either carbon monoxide or carbon dioxide, and be sourced from biomass, Direct Air Capture, or from the ocean. “Old” carbon would come from the “deeper” geological carbon cycle, such as from fossil fuel, or industrial processes such as the manufacture of chemicals from minerals and/or rocks.

Precursors to Renewable Gas also interest me, as transitions are important – transitions from a totally fossil fuel-based gas system to a sustainable gas system. I have recently looked at some basic analysis on the chemistry of Natural Gas, and its refinery. It seems that methanation could be useful in making sour gas available as sweetened, as long as Renewable Hydrogen is developed for this purpose. It seems that there is a lot of sour gas in remaining reserves, and the kind of CCS (Carbon Capture and Storage) that would be required under emissions controls could make sour gas too expensive to use if it was just washed of acids.

I don’t think the future of energy will be completely electrified – it will take a very long time to roll out 100% Renewable Electricity and there will always be problems transitioning out of liquid fuels to electricity in vehicular transportation.

If you could suggest any names, organisations, university departments, companies, governance bodies that I should contact, or research papers that I should read, I would be highly grateful.